As a base for human transcriptome and functional genomics, we created the "full-length long Japan" (FLJ) collection of sequenced human cDNAs. We determined the entire sequence of 21,243 selected clones and found that 14,490 cDNAs (10,897 clusters) were unique to the FLJ collection. About half of them (5,416) seemed to be protein-coding. Of those, 1,999 clusters had not been predicted by computational methods. The distribution of GC content of nonpredicted cDNAs had a peak at ∼58% compared with a peak at ∼42%for predicted cDNAs. Thus, there seems to be a slight bias against GC-rich transcripts in current gene prediction procedures. The rest of the cDNAs unique to the FLJ collection (5,481) contained no obvious open reading frames (ORFs) and thus are candidate noncoding RNAs. About one-fourth of them (1,378) showed a clear pattern of splicing. The distribution of GC content of noncoding cDNAs was narrow and had a peak at ∼42%, relatively low compared with that of protein-coding cDNAs.
Mutational activation of the Ras oncogene products (H-Ras, K-Ras, and N-Ras) is frequently observed in human cancers, making them promising anticancer drug targets. Nonetheless, no effective strategy has been available for the development of Ras inhibitors, partly owing to the absence of well-defined surface pockets suitable for drug binding. Only recently, such pockets have been found in the crystal structures of a unique conformation of Ras⋅GTP. Here we report the successful development of small-molecule Ras inhibitors by an in silico screen targeting a pocket found in the crystal structure of M-Ras⋅GTP carrying an H-Ras–type substitution P40D. The selected compound Kobe0065 and its analog Kobe2602 exhibit inhibitory activity toward H-Ras⋅GTP-c-Raf-1 binding both in vivo and in vitro. They effectively inhibit both anchorage-dependent and -independent growth and induce apoptosis of H- ras G12V –transformed NIH 3T3 cells, which is accompanied by down-regulation of downstream molecules such as MEK/ERK, Akt, and RalA as well as an upstream molecule, Son of sevenless. Moreover, they exhibit antitumor activity on a xenograft of human colon carcinoma SW480 cells carrying the K-ras G12V gene by oral administration. The NMR structure of a complex of the compound with H-Ras⋅GTP T35S , exclusively adopting the unique conformation, confirms its insertion into one of the surface pockets and provides a molecular basis for binding inhibition toward multiple Ras⋅GTP-interacting molecules. This study proves the effectiveness of our strategy for structure-based drug design to target Ras⋅GTP, and the resulting Kobe0065-family compounds may serve as a scaffold for the development of Ras inhibitors with higher potency and specificity.
Ras family small GTPases assume two interconverting conformations, "inactive" state 1 and "active" state 2, in their GTPbound forms. Here, to clarify the mechanism of state transition, we have carried out x-ray crystal structure analyses of a series of mutant H-Ras and M-Ras in complex with guanosine 5-(,␥-imido)triphosphate (GppNHp), representing various intermediate states of the transition. Crystallization of H-RasT35S-GppNHp enables us to solve the first complete tertiary structure of H-Ras state 1 possessing two surface pockets unseen in the state 2 or H-Ras-GDP structure. Moreover, determination of the two distinct crystal structures of H-RasT35S-GppNHp, showing prominent polysterism in the switch I and switch II regions, reveals a pivotal role of the guanine nucleotide-mediated interaction between the two switch regions and its rearrangement by a nucleotide positional change in the state 2 to state 1 transition. Furthermore, the 31 P NMR spectra and crystal structures of the GppNHp-bound forms of M-Ras mutants, carrying various H-Ras-type amino acid substitutions, also reveal the existence of a surface pocket in state 1 and support a similar mechanism based on the nucleotide-mediated interaction and its rearrangement in the state 1 to state 2 transition. Intriguingly, the conformational changes accompanying the state transition mimic those that occurred upon GDP/GTP exchange, indicating a common mechanistic basis inherent in the high flexibility of the switch regions. Collectively, these results clarify the structural features distinguishing the two states and provide new insights into the molecular basis for the state transition of Ras protein.Small GTPases Ras (H-Ras, K-Ras, and N-Ras) are the products of the ras proto-oncogenes and presumed to be some of the most promising targets for anti-cancer drug development because of their high frequency of mutational activation in a variety of human cancers (1). Ras functions as a molecular switch by cycling between GTP-bound active and GDP-bound inactive forms in intracellular signaling pathways controlling cell growth and differentiation. Conversion between the GDPbound and the GTP-bound forms is controlled by guanine nucleotide exchange factors and GTPase-activating proteins (2, 3). Ras comprises the Ras family of small GTPases together with a number of its relatives, including Rap1, Rap2, R-Ras, R-Ras2/ TC1, M-Ras/R-Ras3, etc. (1). X-ray crystallographic and NMR analyses of H-Ras and Rap1A, alone or in complex with their effectors, revealed that the exchange of GTP for GDP results in allosteric conformational changes in two adjacent regions, termed switch I (residues 32-38) and switch II (residues 60 -75), and enables Ras to execute downstream signaling through direct interaction with its effectors, such as Raf kinases and phosphoinositide 3-kinases (2, 3). Recent 31 P NMR spectroscopic studies on Ras unveiled its novel structural feature, the conformational dynamics in the GTP-bound form (4). H-Ras and K-Ras in complex with Mg 2ϩ and a non-hydrolyzable GT...
We have isolated 5 cDNA clones (din2, din6, din9, din10 and din11) corresponding to genes, the transcripts of which accumulated in leaves of Arabidopsis thaliana kept in the dark. These cDNA clones encode proteins similar to beta-glucosidase (EC 3.2.1.21, din2), asparagine synthetase (EC 6.3.5.4, din6), phosphomannose isomerase (EC 5.3.1.8, din9), seed imbibition protein (din10) and 2-oxoacid-dependent dioxygenases (din11). Accumulation of the transcripts from din6 and din10 occurred within 3 h after plants were transferred to darkness. The transcripts from din2, din9 and din11 were only detected after 24 h of dark treatment. We also observed the accumulation of the din transcripts in senescing leaves. Application of a photosynthesis inhibitor, 3-(3,4-dichlorophenyl)-1-1-dimethyl-urea, induced the expression of the din genes under illumination. Application of sucrose to detached leaves suppressed the accumulation of the din transcripts in the dark. These results indicate that expression of these genes partly depends on cellular sugar level. The sugar-modulated expression of the din genes suggests that dark-induced expression of these genes might be related to sugar starvation occurring in leaf cells in the dark, when the photosynthesis is hindered.
Ras small GTPases undergo dynamic equilibrium of two interconverting conformations, state 1 and state 2, in the GTPbound forms, where state 2 is recognized by effectors, whereas physiological functions of state 1 have been unknown. Limited information, such as static crystal structures and 31 P NMR spectra, was available for the study of the conformational dynamics. Here we determine the solution structure and dynamics of state 1 by multidimensional heteronuclear NMR analysis of an HRasT35S mutant in complex with guanosine 5-(, ␥-imido)-triphosphate (GppNHp). The state 1 structure shows that the switch I loop fluctuates extensively compared with that in state 2 or H-Ras-GDP. Also, backbone 1 H, 15 N signals for state 2 are identified, and their dynamics are studied by utilizing a complex with c-Raf-1. Furthermore, the signals for almost all the residues of H-Ras⅐GppNHp are identified by measurement at low temperature, and the signals for multiple residues are found split into two peaks corresponding to the signals for state 1 and state 2. Intriguingly, these residues are located not only in the switch regions and their neighbors but also in the rigidly structured regions, suggesting that global structural rearrangements occur during the state interconversion. The backbone dynamics of each state show that the switch loops in state 1 are dynamically mobile on the picosecond to nanosecond time scale, and these mobilities are significantly reduced in state 2. These results suggest that multiconformations existing in state 1 are mostly deselected upon the transition toward state 2 induced by the effector binding.Small GTPases H-Ras, K-Ras, and N-Ras, collectively called Ras, are the products of the ras proto-oncogenes and function as molecular switches by cycling between the GTP-bound active and the GDP-bound inactive forms in intracellular signaling pathways controlling proliferation, differentiation, and apoptosis of cells. GTP hydrolysis on Ras is markedly stimulated by GTPase-activating proteins, whereas conversion from the GDP-bound form to the GTP-bound form is promoted by guanine nucleotide exchange factors (1, 2). Ras comprise the Ras family of small GTPases together with a number of its relatives including Rap1, Rap2, R-Ras, R-Ras2/TCL, M-Ras/RRas3, RalA, RalB, etc. (3). Structural studies of Ras showed that structural differences between the GDP-and GTP-bound forms universally exist in two flexible regions, called switch I (residues 32-38 in H-Ras) and switch II (residues 60 -75 in H-Ras) (1). GTP-sensitive orientation of the switch regions enables Ras to interact with their effectors such as Raf kinases and phosphoinositide 3-kinases (2). Recent 31 P NMR studies suggested that H-Ras in the nucleoside triphosphate form exists in equilibrium between two kinds of conformational states, state 1 and state 2, around the phosphate groups of GTP or its non-hydrolyzable analogues, GppNHp 3 and GTP␥S, bound to the protein (4 -6). This conformational heterogeneity has been commonly observed in a number of Ras homolo...
A major goal of current human genome-wide studies is to identify the genetic basis of complex disorders. However, the availability of an unbiased, reliable, cost efficient and comprehensive methodology to analyze the entire genome for complex disease association is still largely lacking or problematic. Therefore, we have developed a practical and efficient strategy for whole genome association studies of complex diseases by charting the human genome at 100 kb intervals using a collection of 27,039 microsatellites and the DNA pooling method in three successive genomic screens of independent case-control populations. The final step in our methodology consists of fine mapping of the candidate susceptible DNA regions by single nucleotide polymorphisms (SNPs) analysis. This approach was validated upon application to rheumatoid arthritis, a destructive joint disease affecting up to 1% of the population. A total of 47 candidate regions were identified. The top seven loci, withstanding the most stringent statistical tests, were dissected down to individual genes and/or SNPs on four chromosomes, including the previously known 6p21.3-encoded Major Histocompatibility Complex gene, HLA-DRB1. Hence, microsatellite-based genome-wide association analysis complemented by end stage SNP typing provides a new tool for genetic dissection of multifactorial pathologies including common diseases.
Rheumatoid arthritis (RA) is a chronic inflammatory joint disease with a complex etiology in which environmental factors within a genetically susceptible host maneuver the innate and adaptive arms of the immune system toward recognition of autoantigens. This ultimately leads to joint destruction and clinical symptomatology. Despite the identification of a number of disease-susceptibility regions across the genome, RA's major genetic linkage remains with the major histocompatibility complex (MHC), which contains not only the key immune-response class I and class II genes but also a host of other loci, some with potential immunological relevance. Inside the MHC itself, the sole consistent RA association is that with HLA-DRB1, although this does not encode all MHC-related susceptibility. Indeed, in a set of Japanese patients with RA and a control group, we previously reported the presence of a second RA-susceptibility gene within the telomeric human leukocyte antigen (HLA) class III region. Using microsatellites, we narrowed the susceptibility region to 70 kb telomeric of the TNF cluster, known to harbor four expressed genes (I kappa BL, ATP6G, BAT1, and MICB). Here, using numerous single-nucleotide polymorphisms (SNPs) and insertion/deletion polymorphisms, we identify the second RA-susceptibility locus within the HLA region, as the T allele of SNP 96452 (T/A), in the promoter region (position -62) of the I kappa BL gene (P=.0062). This -62T/A SNP disrupts the putative binding motif for the transcriptional repressor, delta EF1, and hence may influence the transcription of I kappa BL, homologous to I kappa B alpha, the latter being a known inhibitor of NF kappa B, which is central to innate immunity. Therefore, the MHC may harbor RA genetic determinants affecting the innate and adaptive arms of the immune system.
The Rap1 small GTPase has been implicated in regulation of integrin-mediated leukocyte adhesion downstream of various chemokines and cytokines in many aspects of inflammatory and immune responses. However, the mechanism for Rap1 regulation in the adhesion signaling remains unclear. RA-GEF-2 is a member of the multiple-member family of guanine nucleotide exchange factors (GEFs) for Rap1 and characterized by the possession of a Ras/Rap1-associating domain, interacting with M-Ras-GTP as an effector, in addition to the GEF catalytic domain. Here, we show that RA-GEF-2 is specifically responsible for the activation of Rap1 that mediates tumor necrosis factor-␣ (TNF-␣)-triggered integrin activation. In BAF3 hematopoietic cells, activated M-Ras potently induced lymphocyte function-associated antigen 1 (LFA-1)-mediated cell aggregation. This activation was totally abrogated by knockdown of RA-GEF-2 or Rap1. TNF-␣ treatment activated LFA-1 in a manner dependent on M-Ras, RA-GEF-2, and Rap1 and induced activation of M-Ras and Rap1 in the plasma membrane, which was accompanied by recruitment of RA-GEF-2. Finally, we demonstrated that M-Ras and RA-GEF-2 were indeed involved in TNF-␣-stimulated and Rap1-mediated LFA-1 activation in splenocytes by using mice deficient in RA-GEF-2. These findings proved a crucial role of the cross-talk between two Ras-family GTPases M-Ras and Rap1, mediated by RA-GEF-2, in adhesion signaling.
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