The solution structure of the tumor suppressor p16INK4A has been determined by NMR, and important recognition regions of both cdk4 and p16INK4A have been identified. The tertiary structure of p16INK4A contains four helix-turn-helix motifs linked by three loops. Twelve tumorigenic mutants of p16INK4A have been constructed and analyzed for their structure and activity, and new mutants have been designed rationally. A fragment of 58 residues at the N terminus of cdk4 important for p16INK4A binding has been identified. The importance of this region was further verified by mutational analysis of cdk4. These results and docking experiments have been used to assess possible modes of binding between p16INK4A and cdk4.
The tumor suppressor p16INK4A with eight N-terminal amino acids deleted (p16/delta 1-8) was expressed in Escherichia coli without any fusion artifacts and purified. The integrity of p16/delta 1-8 was confirmed by mass spectrometry, and its activity was demonstrated by in vitro cdk4 inhibition assay. Various physical methods were used to characterize the molecular and structural properties of p16/delta 1-8. The protein was found to oligomerize in vitro, as demonstrated by gel electrophoresis, mass spectrometry, and NMR. Various approaches, including changes of concentration and pH, additions of salts, detergents, and various organic solvents, and construction of a C-terminal deletion mutant and a cysteine mutant were used to try to reduce the extent of oligomerization. Only decreasing the protein concentration was found to reduce oligomerization. The affinity between p16 molecules in vivo was demonstrated by the yeast two-hybrid system. The protein was found to be very unstable on the basis of urea- and guanidinium chloride-induced denaturation studies monitored by NMR and CD, respectively. Despite these unfavorable properties, total NMR assignments were accomplished with uniform 13C and 15N isotope labeling. All multidimensional NMR experiments were performed at a very low concentration of 0.2 mM. The secondary structure was then determined from the NMR data. The results of NMR and CD studies indicate that the protein is highly alpha-helical, and the ankyrin repeat sequences show helix-turn-helix structures. This is the first structural information obtained for the important motif of ankyrin repeats. Overall, p16/delta 1-8 appears to be conformationally flexible. In order to understand the structural basis of the functional changes for some mutants existing in tumor cells, several missense mutants of p16/delta 1-8 were constructed. Four of them were expressed at high levels and purified. The molecular and structural properties of these mutants were analyzed by CD and NMR and compared with the corresponding properties of wild-type p16/delta 1-8. The results suggest that the functional changes in P114L and G101W are likely to be related to global conformational changes. In addition, we have demonstrated that the tendency of aggregation increases significantly by a single D84H mutation.
We describe a transcriptional analysis platform consisting of a universal micro-array system (UMAS) combined with an enzymatic manipulation step that is capable of generating expression profiles from any organism without requiring a priori species-specific knowledge of transcript sequences. The transcriptome is converted to cDNA and processed with restriction endonucleases to generate low-complexity pools (approximately 80-120) of equal length DNA fragments. The resulting material is amplified and detected with the UMAS system, comprising all possible 4,096 (4(6)) DNA hexamers. Ligation to the arrays yields thousands of 14-mer sequence tags. The compendium of signals from all pools in the array-of-universal arrays comprises a full-transcriptome expression profile. The technology was validated by analysis of the galactose response of Saccharomyces cerevisiae, and the resulting profiles showed excellent agreement with the literature and real-time PCR assays. The technology was also used to demonstrate expression profiling from a hybrid organism in a proof-of-concept experiment where a T-cell receptor gene was expressed in yeast.
V(D)J recombination plays a prominent role in the generation of the antigen receptor repertoires of B and T lymphocytes. It is also likely to be involved in the formation of chromosomal translocations, some of which may result from interchromosomal recombination. We have investigated the potential of the V(D)J recombination machinery to perform intermolecular recombination between two plasmids, either unlinked or linked by catenation. In either case, recombination occurs in trans to yield signal and coding joints, and the results do not support the existence of a mechanistic block to the formation of coding joints in trans. Instead, we observe that linearization of the substrate, which does not alter the cis or trans status of the recombination signals, causes a specific and dramatic reduction in coding joint formation. This unexpected result leads us to propose a "release and recapture" model for V(D)J recombination in which coding ends are frequently released from the postcleavage complex and the efficiency of coding joint formation is influenced by the efficiency with which such ends are recaptured by the complex. This implies the existence of mechanisms, operative during recombination of chromosomal substrates, that act to prevent coding end release or to facilitate coding end recapture.V(D)J recombination is the process of assembly of T-cell receptor and immunoglobulin genes from V, J, and sometimes D gene segments (1). Lymphoid-specific proteins RAG1 (recombination activating gene 1) and RAG2 (2, 3) and multiple ubiquitously expressed protein factors are essential for V(D)J recombination. RAG1 and RAG2 bind to and cleave at specific recombination signal sequences (RSSs) 1 generating blunt signal ends and covalently sealed, hairpin coding ends (4 -7). RSSs consist of conserved heptamer and nonamer sequences separated by a nonconserved spacer 12 or 23 base pairs long (12-and 23-RSS). V(D)J recombination occurs efficiently in vivo only between RSSs with different spacer lengths, a restriction known as the 12/23 rule (8).Recent biochemical studies indicate that V(D)J recombination proceeds through a series of protein-DNA complexes. Prior to cleavage, the RAG1 and RAG2 proteins form stable complexes with individual and synapsed pairs of RSSs (9 -17). After cleavage, the RAG proteins remain tightly bound to a synapsed pair of signal ends (15, 18) and also appear to interact with the two hairpin coding ends, albeit with lower affinity (15). Therefore, the immediate product of cleavage is thought to be a "cleaved signal complex" containing the four free ends (15).Usually, RSSs involved in V(D)J recombination are located on the same chromosome, i.e. in cis. However, V(D)J recombination has been implicated in the formation of chromosomal translocations leading to lymphoid malignancies (19 -23). In certain cases, such translocations could be the result of V(D)J recombination occurring in trans, using RSSs on different chromosomes. There have been attempts to address this issue. The first such study attempted, and fai...
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