A KRAS GTPase K104Q Mutant Retains Downstream Signaling by Offsetting Defects in Regulation.

The KRAS GTPase plays a critical role in the control of cellular growth. The activity of KRAS is regulated by guanine nucleotide exchange factors (GEFs), GTPase-activating proteins (GAPs), and also post-translational modification. Lysine 104 in KRAS can be modified by ubiquitylation and acetylation, but the role of this residue in intrinsic KRAS function has not been well characterized. We find that lysine 104 is important for GEF recognition, because mutations at this position impaired GEF-mediated nucleotide exchange. Because the KRAS K104Q mutant has recently been employed as an acetylation mimetic, we conducted a series of studies to evaluate its in vitro and cell-based properties. Herein, we found that KRAS K104Q exhibited defects in both GEF-mediated exchange and GAP-mediated GTP hydrolysis, consistent with NMR-detected structural perturbations in localized regions of KRAS important for recognition of these regulatory proteins. Despite the partial defect in both GEF and GAP regulation, KRAS K104Q did not alter steady-state GTP-bound levels or the ability of the oncogenic KRAS G12V mutant to cause morphologic transformation of NIH 3T3 mouse fibroblasts and of WT KRAS to rescue the growth defect of mouse embryonic fibroblasts deficient in all Ras genes. We conclude that the KRAS K104Q mutant retains both WT and mutant KRAS function, probably due to offsetting defects in recognition of factors that up-regulate (GEF) and down-regulate (GAP) RAS activity.

Gateway cloning for protein expression.

The rate-limiting step in protein production is usually the generation of an expression clone that is capable of producing the protein of interest in soluble form at high levels. Although cloning of genes for protein expression has been possible for some time, efficient generation of functional expression clones, particularly for human proteins, remains a serious bottleneck. Often, such proteins are hard to produce in heterologous systems because they fail to express, are expressed as insoluble aggregates, or cannot be purified by standard methods. In many cases, researchers are forced to return to the cloning stages to make a new construct with a different purification tag, or perhaps to express the protein in a different host altogether. This usually requires identifying new cloning schemes to move a gene from one vector to another, and frequently requires multistep, inefficient cloning processes, as well as lengthy verification and sequence analysis. Thus, most researchers view this as a linear pathway - make an expression clone, try it out, and if it fails, go back to the beginning and start over. Because of this, protein expression pipelines can be extremely expensive and time consuming.The advent of recombinational cloning has dramatically changed the way protein expression can be handled. Rapid production of parallel expression clones is now possible at relatively low cost, opening up many possibilities for both low- and high-throughput protein expression, and increasing the flexibility of expression systems that researchers have available to them. While many different recombinational cloning systems are available, the one with the highest level of flexibility remains the Gateway system. Gateway cloning is rapid, robust, and highly amenable to high-throughput parallel generation of expression clones for protein production.

Combinatorial assembly of clone libraries using site-specific recombination.

Generation of DNA clones for use in proteomic and genomic research often requires a significant level of parallel production, as the number of downstream options for these experiments increases. Where a single fluorescently tagged construct may have sufficed before, there is now the need for multiple types of labels for different readouts and different assays. Protein expression, which once utilized a very small set of vectors because of low throughput expression and purification, has now rapidly matured into a high throughput system in which dozens of conditions can be tested in parallel to identify the best candidate clones. This has returned the bottleneck in many of these technologies to the generation of DNA clones, and standard cloning techniques often dramatically limit the throughput and success of such processes. In order to overcome this bottleneck, higher-throughput and more parallel cloning processes need to be developed which would allow rapid, inexpensive production of final clones. In addition, there is a strong need to utilize standardized elements to avoid unnecessarily remaking fragments of clones that could be used in multiple constructs. The advent of recombinational cloning helped to increase the parallel processing of DNA clones, but was still limited by the need to generate different vector backbones for each specific need. The solution to this problem emerged with the introduction of combinatorial approaches to clone construction, based on either homologous or site-specific recombination processes. In particular, the Gateway Multisite system provides all of the necessary components for a highly parallel, inexpensive, rapid, and diverse platform for clone construction in many areas of proteomic and genomic research. Here we describe our optimized system for combinatorial cloning, including improvements in cloning protocols and construct design that permit users to easily generate libraries of clones which can be combined in parallel to create an unlimited number of final constructs. The system is capable of utilizing the tens of thousands of commercially available Gateway clones already in existence, and allows easy adaptation of most DNA vectors to the system.