Biochemical and Structural Analysis of Common Cancer-Associated KRAS Mutations.

UNLABELLED: KRAS mutations are the most common genetic abnormalities in cancer, but the distribution of specific mutations across cancers and the differential responses of patients with specific KRAS mutations in therapeutic clinical trials suggest that different KRAS mutations have unique biochemical behaviors. To further explain these high-level clinical differences and to explore potential therapeutic strategies for specific KRAS isoforms, we characterized the most common KRAS mutants biochemically for substrate binding kinetics, intrinsic and GTPase-activating protein (GAP)-stimulated GTPase activities, and interactions with the RAS effector, RAF kinase. Of note, KRAS G13D shows rapid nucleotide exchange kinetics compared with other mutants analyzed. This property can be explained by changes in the electrostatic charge distribution of the active site induced by the G13D mutation as shown by X-ray crystallography. High-resolution X-ray structures are also provided for the GDP-bound forms of KRAS G12V, G12R, and Q61L and reveal additional insight. Overall, the structural data and measurements, obtained herein, indicate that measurable biochemical properties provide clues for identifying KRAS-driven tumors that preferentially signal through RAF. IMPLICATIONS: Biochemical profiling and subclassification of KRAS-driven cancers will enable the rational selection of therapies targeting specific KRAS isoforms or specific RAS effectors.

In situ selectivity profiling and crystal structure of SML-8-73-1, an active site inhibitor of oncogenic K-Ras G12C.

Directly targeting oncogenic V-Ki-ras2 Kirsten rat sarcoma viral oncogene homolog (K-Ras) with small-molecule inhibitors has historically been considered prohibitively challenging. Recent reports of compounds that bind directly to the K-Ras G12C mutant suggest avenues to overcome key obstacles that stand in the way of developing such compounds. We aim to target the guanine nucleotide (GN)-binding pocket because the natural contents of this pocket dictate the signaling state of K-Ras. Here, we characterize the irreversible inhibitor SML-8-73-1 (SML), which targets the GN-binding pocket of K-Ras G12C. We report a high-resolution X-ray crystal structure of G12C K-Ras bound to SML, revealing that the compound binds in a manner similar to GDP, forming a covalent linkage with Cys-12. The resulting conformation renders K-Ras in the open, inactive conformation, which is not predicted to associate productively with or activate downstream effectors. Conservation analysis of the Ras family GN-binding pocket reveals variability in the side chains surrounding the active site and adjacent regions, especially in the switch I region. This variability may enable building specificity into new iterations of Ras and other GTPase inhibitors. High-resolution in situ chemical proteomic profiling of SML confirms that SML effectively discriminates between K-Ras G12C and other cellular GTP-binding proteins. A biochemical assay provides additional evidence that SML is able to compete with millimolar concentrations of GTP and GDP for the GN-binding site.

Investigating the deep supercooling ability of an Alaskan beetle, Cucujus clavipes puniceus, via high throughput proteomics.

Cucujus clavipes puniceus is a freeze avoiding beetle capable of surviving the long, extremely cold winters of the Interior of Alaska. Previous studies showed that some individuals typically supercool to mean values of approximately -40 °C, with some individuals supercooling to as low as -58 °C, but these non-deep supercooling (NDSC) individuals eventually freeze if temperatures drop below this. However, other larvae, especially if exposed to very cold temperatures, supercool even further. These deep supercooling (DSC) individuals do not freeze even if cooled to -100 °C. In addition, the body water of the DSC larvae vitrifies (turns to a glass) at glass transition temperatures of -58 to -70 °C. This study examines the proteomes of DSC and NDSC larvae to assess proteins that may contribute to or inhibit the DSC trait. Using high throughput proteomics, we identified 138 proteins and 513 Gene Ontology categories in the DSC group and 104 proteins and 573 GO categories in the NDSC group. GO categories enriched in DSC include alcohol metabolic process, cellular component morphogenesis, monosaccharide metabolic process, regulation of biological quality, extracellular region, structural molecule activity, and antioxidant activity. Proteins unique to DSC include alpha casein precursor, alpha-actinin, vimentin, tropomyosin, beta-lactoglobulin, immunoglobulins, tubulin, cuticle proteins and endothelins.

Elucidating the biochemical overwintering adaptations of Larval Cucujus clavipes puniceus, a nonmodel organism, via high throughput proteomics.

Cucujus clavipes puniceus (C.c.p.) is a nonmodel, freeze-avoiding beetle that overwinters as extremely cold-tolerant larvae in the interior boreal forests of Alaska to temperatures as low as -100 °C. Using a tandem MS-based approach, we compared the proteomes of winter- and summer-collected C.c.p. to identify proteins that may play functional roles in successful overwintering. Using Gene Ontology (GO) analysis and manual interpretation, we identified 104 proteins in winter and 128 proteins in summer samples. We found evidence to indicate a cytoskeletal rearrangement between seasons, with Winter NDSC possessing unique actin and myosin isoforms while summer larvae up-regulated α actinin, tubulin, and tropomyosin. We also detected a fortification of the cuticle in winter via unique cuticle proteins, specifically larval/pupal rigid cuticle protein 66 precursor and larval cuticle protein A2B. Also, of particular interest in the winter larvae was an up-regulation of proteins related to silencing of genes (bromodomain adjacent to zinc finger domain 2A and antisilencing protein 1), proteins involved with metabolism of amines (2-isopropylmalate synthase and dihydrofolate reductase), and immune system process (lysozyme C precursor), among others. This represents the first high throughput MS/MS analysis of a nonmodel, cold-tolerant organism without a concurrent microarray analysis.

A cross-species compendium of proteins/gene products related to cold stress identified by bioinformatic approaches.

The purpose of this investigation was to construct a compendium of low temperature responsive proteins/gene products across species as identified by bioinformatics based approaches, thus allowing low temperature researchers a searchable database. Another purpose was to identify specific low temperature responsive proteins/gene products across at least two different species. We generated a database containing 2030 low temperature responsive protein/gene product entries, of which 1353 were up-regulated and 549 were down-regulated in response to various cold exposures across 34 different species; including bacteria (9 species), yeast (1 species), animals (including nematodes (1 species), collembola (2 species), insects (5 species), fish (1 species), amphibians (1 species), reptiles (1 species), mammals (2 species)), and plants (moss (1 species), gymnosperms (1 species) and angiosperms (9 species)). There were 39 studies using 12 different cold treatments; 20 used proteomics and 18 used transcriptomics. Concerning our purpose of identifying specific temperature responsive proteins/gene products across species, we found 113 shared proteins/gene products groups, each of which was found in at least two species. Of these shared proteins/gene products groups, 58 proteins/gene products (including protein/gene product families) that were consistently regulated, meaning always either up- or down-regulated, across species. Another 23 proteins/gene products were inconsistently regulated, meaning that the proteins/gene products were up-regulated in some species and treatments while being down-regulated in other species and treatments. An additional 32 proteins/gene products that are part of larger family headings and are difficult to separate from related member proteins (such the ribosomal proteins, 30S, 50S, and others) were inconsistently regulated. This work is an attempt to create a centralized database and repository for low temperature responsive proteins/gene products in all species.