Backbone resonance assignment for the outer membrane lipoprotein receptor LolB from Escherichia coli

LolB, which is anchored to the outer membrane of Gram-negative bacteria, receives outer-membrane-directed lipoproteins from LolA, and incorporates them into the outer membrane. We established backbone resonance assignments of ²H/¹³C/¹⁵N labeled LolB from Escherichia coli.     

The Role of c-kit Proto-oncogene during Melanocyte Development in Mouse. In vivo Approach by the In utero Microinjection of Anti-c-kit Antibody

In order to investigate the role of the c- kit oncogene in the melanoblast development, a rat monoclonal antibody (ACK2) against the mouse c-kit protein was used to localize cells expressing c-kit during fetal development. ACK2 was also injected directly into the amniotic cavity of mouse fetuses at successive developmental stages. After birth, the offspring were examined to determine the resulting coat color patterns. c-kit positive melanoblasts first appeared in dermis of fetuses at 11.5 days postcoitum (dpc). Subsequently, these cells increased in number and migrated dorsolaterally to the ventral region, and by 12.5 dpc some of them began to invade the epidermis. Treatment of fetuses by ACK2 microinjection appeared to affect the pigmentation in the coat, inducing a variety of spotting patterns in offspring, and the location of the spots was closely correlated with gestational stage. ACK2 injection of early fetuses produced major changes in coat color even though few c-kit positive cells were detectable in the dermal mesenchyme at the time of injection. Large spots were also induced when mid-stage fetuses with a only few c-kit positive cells in the dorsal region were injected. By contrast, except for spot formation in the center of ventral region, ACK2 injection did not appear to affect melanogenesis in late stage fetuses that had many c-kit positive cells.     

An NMR method for the determination of protein binding interfaces using TEMPOL-induced chemical shift perturbations

Background

The determination of protein–protein interfaces is of crucial importance to understand protein function and to guide the design of compounds. To identify protein–protein interface by NMR spectroscopy, ¹³C NMR paramagnetic shifts induced by freely diffusing 4-hydroxy-2, 2, 6, 6-tetramethyl-piperidine-1-oxyl (TEMPOL) are promising, because TEMPOL affects distinct ¹³C NMR chemical shifts of the solvent accessible nuclei belonging to proteins of interest, while ¹³C nuclei within the interior of the proteins may be distinguished by a lack of such shifts.

Method

We measured the ¹³C NMR paramagnetic shifts induced by TEMPOL by recording ¹³C–¹³C TOCSY spectra for ubiquitin in the free state and the complex state with yeast ubiquitin hydrolase1 (YUH1).

Results

Upon complexation of ubiquitin with YUH1, ¹³C NMR paramagnetic shifts associated with the protein binding interface were reduced by 0.05 ppm or more. The identified interfacial atoms agreed with the prior X-ray crystallographic data.

Conclusions

The TEMPOL-induced ¹³C chemical shift perturbation is useful to determine precise protein–protein interfaces.

General significance

The present method is a useful method to determine protein–protein interface by NMR, because it has advantages in easy sample preparations, simple data analyses, and wide applicabilities.     

A facile synthesis of 5'-end solid-anchored, 3'-end free oligodeoxyribonucleotides via the (5'-->3')-elongated phosphoramidite strategy

It is demonstrated that not only N2- but also O6-protection of the guanine base is necessary for obtaining the oligodeoxyribonucleotides in high yields and at a high purity in the solid-phase synthesis via the (5'--> 3')-chain elongated phosphoramidite approach.     

Localized suppression of RhoA activity by Tyr31/118-phosphorylated paxillin in cell adhesion and migration

RhoA activity is transiently inhibited at the initial phase of integrin engagement, when Cdc42- and/or Rac1-mediated membrane spreading and ruffling predominantly occur. Paxillin, an integrin-assembly protein, has four major tyrosine phosphorylation sites, and the phosphorylation of Tyr31 and Tyr118 correlates with cell adhesion and migration. We found that mutation of Tyr31/118 caused enhanced activation of RhoA and premature formation of stress fibers with substantial loss of efficient membrane spreading and ruffling in adhesion and migration of NMuMG cells. These phenotypes were similar to those induced by RhoA(G14V) in parental cells, and could be abolished by expression of RhoA(T19N), Rac1(G12V), or p190RhoGAP in the mutant-expressing cells. Phosphorylated Tyr31/118 was found to bind to two src homology (SH)2 domains of p120RasGAP, with coprecipitation of endogenous paxillin with p120RasGAP. p190RhoGAP is known to be a major intracellular binding partner for the p120RasGAP SH2 domains. We found that Tyr31/118-phosphorylated paxillin competes with p190RhoGAP for binding to p120RasGAP, and provides evidence that p190RhoGAP freed from p120RasGAP efficiently suppresses RhoA activity during cell adhesion. We conclude that Tyr31/118-phosphorylated paxillin serves as a template for the localized suppression of RhoA activity and is necessary for efficient membrane spreading and ruffling in adhesion and migration of NMuMG cells.     

Biology of mammary fat pad in fetal mouse: capacity to support development of various fetal epithelia in vivo

Epithelia from the lobular part of submandibular salivary gland, glandular stomach, intestine and colon of 14-day C3H/HeN fetuses, and from pituitary gland and pancreas of 12-day fetuses were recombined with 14-day mammary fat pad precursor tissue and syngrafted under the kidney capsule. The normal organogenetic development typical of the epithelium occurred. The same epithelia taken from earlier stage fetuses did not develop normally. Thus, 14-day fetal mouse mammary fat pad precursor tissue has the capacity to support normal organogenesis of various fetal epithelia of developmentally advanced stages. This supportive capacity is decreased in the fat pad precursor tissue of 17- to 18-day fetal mice and is entirely lost postnatally.     

Collagen-binding mode of vWF-A3 domain determined by a transferred cross-saturation experiment

The nature of the supramolecular complex between fibrillar collagen and collagen-binding proteins (CBPs) has hindered detailed X-ray and NMR analyses of the ligand-recognition mechanism at atomic resolution because of the lack of appropriate approaches for studying large heterogeneous supramolecular complexes. Recently, we proposed an NMR method, termed transferred cross-saturation (TCS), that enables the rigorous identification of contact residues in a huge protein complex. Here we used TCS to study the supramolecular complex between the A3 domain of von Willebrand factor and fibrillar collagen, which allowed the successful determination of the ligand-binding site of the A3 domain. The binding site of the A3 domain was located at its hydrophobic 'front' surface and was completely different from that of the I domain from the a2 subunit of integrin (alpha2-I domain), which was reported to be the hydrophilic 'top' surface of alpha2-I, although the A3 domain and the alpha2-I domain share a similar fold and possess the identical function of collagen binding.