Structural analysis of biological aliphatic compounds using surface-enhanced Fourier transform Raman spectroscopy

The surface-enhanced Raman scattering (SERS) technique for Fourier transform Raman spectrometry is employed to reveal the chemical structure of biological aliphatic compounds consisting of folded, long aliphatic chains. The structural analysis is performed via the measurements of the accordion-vibration modes generated in the ordered, long aliphatic chain. The SERS spectra after subtraction of a background spectrum give segment lengths that are almost perfectly consistent with the chemical structures studied by mass spectrometry. The agreement of the SERS results with those of mass spectrometry suggests the positions of kinks in the long hydrocarbon chain. The combination technique of SERS and mass spectrometry is useful to discuss the structure of folded, long biological lipids.     

The region adjacent to the highly immunogenic site and shielded by the middle domain is responsible for self-oligomerization/client binding of the HSP90 molecular chaperone

We here investigated the mechanism of self-oligomerization of the 90-kDa heat shock protein (HSP90) molecular chaperone, because it is known that this oligomerization reflects the client-binding activity. The transition temperatures for the self-oligomerization of the full-length forms of human HSP90alpha and HtpG (bacterial HSP90), i.e., 45 and 60 degrees C, respectively, were identical to those for the dissociation of the recombinant N domain (residues 1-400 of human HSP90alpha and residues 1-336 of HtpG in our definition) from the remainder of the molecule. The N domain of human HSP90alpha expressed in Escherichia coli was oligomeric, and the oligomerization activity was localized within residues 311-350, i.e., C-terminally adjacent to the highly immunogenic site (residues 291-304). Particularly, residues 341-350 were critical on oligomerization. On the other hand, residues 289-389 were indispensable for the interaction with the M domain (residues 401-618) of the molecule. Oligomer formation of the N domain was efficiently suppressed by its extension until Lys546, i.e., residues 401-546, which is required for the interaction with the N domain. Among highly conserved amino acids at residues 289-400, Trp297, Pro379, and Phe384 were essential for the interaction with the M domain. With these observations taken together, we propose as the activation mechanism of HSP90 molecular chaperone that heat stress induces the liberation of the oligomerization/client-binding site of residues 311-350 by disrupting the intramolecular interaction between residues 289-389 and 401-546.     

Abundant retention and release of connective tissue growth factor (CTGF/CCN2) by platelets

Wound healing and tissue regeneration are usually initiated by coagulation followed by fibrous tissue formation. In the present study, we discovered an abundance of connective tissue growth factor (CTGF/CCN2) in human platelets, which was released along with the coagulation process. The CTGF/CCN2 content in platelets was 10-fold higher than that in arterial tissue. Furthermore, the CTGF/CCN2 content in a single platelet was computed to be more than 20-fold higher than that of any other growth factor reported. Considering that CTGF/CCN2 promotes angiogenesis, cartilage regeneration, fibrosis and platelet adhesion, it may be now regarded as one of the major functional components of platelets.     

Evolutionary dynamics of insertion sequences in Helicobacter pylori

Prokaryotic insertion sequence (IS) elements behave like parasites in terms of their ability to invade and proliferate in microbial gene pools and like symbionts when they coevolve with their bacterial hosts. Here we investigated the evolutionary history of IS605 and IS607 of Helicobacter pylori, a genetically diverse gastric pathogen. These elements contain unrelated transposase genes (orfA) and also a homolog of the Salmonella virulence gene gipA (orfB). A total of 488 East Asian, Indian, Peruvian, and Spanish isolates were screened, and 18 and 14% of them harbored IS605 and IS607, respectively. IS605 nucleotide sequence analysis (n = 42) revealed geographic subdivisions similar to those of H. pylori; the geographic subdivision was blurred, however, due in part to homologous recombination, as indicated by split decomposition and homoplasy tests (homoplasy ratio, 0.56). In contrast, the IS607 populations (n = 44) showed strong geographic subdivisions with less homologous recombination (homoplasy ratio, 0.2). Diversifying selection (ratio of nonsynonymous change to synonymous change, >1) was evident in approximately 15% of the IS605 orfA codons analyzed but not in the IS607 orfA codons. Diversifying selection was also evident in approximately 2% of the IS605 orfB and approximately 10% of the IS607 orfB codons analyzed. We suggest that the evolution of these elements reflects selection for optimal transposition activity in the case of IS605 orfA and for interactions between the OrfB proteins and other cellular constituents that potentially contribute to bacterial fitness. Taken together, similarities in IS elements and H. pylori population genetic structures and evidence of adaptive evolution in IS elements suggest that there is coevolution between these elements and their bacterial hosts.     

Rapid degradation of Cdt1 upon UV-induced DNA damage is mediated by SCFSkp2 complex

Cdt1 is a licensing factor for DNA replication, the function of which is tightly controlled to maintain genome integrity. Previous studies have indicated that the cell cycle-dependent degradation of Cdt1 is triggered at S phase to prevent re-replication. In this study, we found that Cdt1 is degraded upon DNA damage induced by either UV treatment or gamma-irradiation (IR). Although the IR-triggered degradation of Cdt1 was caffeine-insensitive, the UV-triggered degradation of Cdt1 was caffeine-sensitive. This indicates that the cells treated with UV utilize the checkpoint pathway, which differs from that triggered by IR. A recent study has suggested that Cdt1 is phosphorylated, ubiquitylated, and degraded at the G(1)/S boundary in the normal cell cycle. Treatment with MG132, a proteasome inhibitor, inhibited the degradation of Cdt1 and resulted in the accumulation of the phosphorylated form of Cdt1 after UV treatment. In the case of UV treatment, phosphorylation of Cdt1 induced the recruitment of Cdt1 to a SCF(Skp2) complex. Moreover, ectopic overexpression of Cdt1 after UV treatment interfered the inhibition of DNA synthesis. These results indicate that Cdt1 is a target molecule of the cell cycle checkpoint in UV-induced DNA damage.     

S-glutathiolation of Ras mediates redox-sensitive signaling by angiotensin II in vascular smooth muscle cells

Angiotensin II (AII) increases production of reactive oxygen species from NAD(P)H oxidase, a response that contributes to vascular hypertrophy. Here we show in cultured vascular smooth muscle cells that S-glutathiolation of the redox-sensitive Cys(118) on the small GTPase, Ras, plays a critical role in AII-induced hypertrophic signaling. AII simultaneously increased the Ras activity and the S-glutathiolation of Ras (GSS-Ras) detected by biotin-labeled GSH or mass spectrometry. Both the increase in activity and GSS-Ras was labile under reducing conditions, suggesting the essential nature of this thiol modification to Ras activation. Overexpression of catalase, a dominant-negative p47(phox), or glutaredoxin-1 decreased GSS-Ras, Ras activation, p38, and Akt phosphorylation and the induction of protein synthesis by AII. Furthermore, expression of a Cys(118) mutant Ras decreased AII-mediated p38 and Akt phosphorylation as well as protein synthesis. These results show that H(2)O(2) from NAD(P)H oxidase forms GSS-Ras on Cys(118) and increases its activity leading to p38 and Akt phosphorylation, which contributes to the induction of protein synthesis. This study suggests that GSS-Ras is a redox-sensitive signaling switch that participates in the cellular response to AII.     

Resonant mirror biosensor detection method based on yessotoxin-phosphodiesterase interactions

Yessotoxin (YTX) is a generic name for a group of lipophilic compounds recently discovered and chemically characterized. Association measurements were done in a resonant mirror biosensor. The instrument detects changes in the refractive index and/or thickness occurring within a few hundred nanometers form the sensor surface where a molecule is attached. We used aminosilane surfaces where phosphodiesterase 3',5'-cyclic-nucleotide-specific from bovine brain (PDEs) was immobilized. Over this immobilized ligand different amounts of YTX were added and typical association curve profiles were observed. These association curves fit a pseudo-first-order kinetic equation where the apparent association rate constant (k(on)) can be calculated. The value of this constant increases with YTX concentration. From the representation of k(on) versus YTX concentration we obtained the association rate constant (k(ass)) 248+/-40 M(-1)s(-1) and the dissociation rate constant (k(diss)) 9.36 x 10(-4)+/-1.72 x 10(-4)s(-1). From these values the kinetic equilibrium dissociation constant (K(D)) for YTX-PDEs association can be calculated. The value of this last constant is 3.74 x 10(-6)+/-8.25 x 10(-8)M YTX. The PDE-YTX association was used as a method suitable for determination of the toxin concentration in a shellfish sample. The assay had sufficient sensitivity and can be used on simple shellfish extracts.     

Lineage-specific cell disruption in living mice by Cre-mediated expression of diphtheria toxin A chain

We have established a transgenic mouse line in which floxed neomycin resistant cassette was inserted between the CAG promoter and EGFP. When these transgenic mice were mated with Cre-expressing transgenic animals, the offspring obtained were fluorescent green. We then established a transgenic mouse line in which EGFP in the above construct was replaced by diphtheria toxin A chain (DT). When the latter transgenic mice were mated with mice expressing Cre restricted to germ cells, we obtained healthy but sterile offspring due to a disruption of germ line cells by DT expression. We predict that this strategy will be useful for the construction of new animal models for human diseases, featuring a variety of missing cell lineages produced by disruption with DT.