The impact of the chalcogen-substitution element and initial spectroscopic state on excited-state relaxation pathways in nucleobase photosensitizers: a combination of static and dynamic studies.

The substitution of oxygen with chalcogen in carbonyl group(s) of canonical nucleobases gives an impressive triplet generation, enabling their promising applications in medicine and other emerging techniques. The excited-state relaxation S2(ππ*) → S1(nπ*) → T1(ππ*) has been considered the preferred path for triplet generation in these nucleobase derivatives. Here, we demonstrate enhanced quantum efficiency of direct intersystem crossing from S2 to triplet manifold upon substitution with heavier chalcogen elements. The excited-state relaxation dynamics of sulfur/selenium substituted guanines in a vacuum is investigated using a combination of static quantum chemical calculations and on-the-fly excited-state molecular dynamics simulations. We find that in sulfur-substitution the S2 state predominantly decays to the S1 state, while upon selenium-substitution the S2 state deactivation leads to simultaneous population of the S1 and T2,3 states in the same time scale and multi-state quasi-degeneracy region S2/S1/T2,3. Interestingly, the ultrafast deactivation of the spectroscopic S3 state of both studied molecules to the S1 state occurs through a successive S3 → S2 → S1 path involving a multi-state quasi-degeneracy S3/S2/S1. The populated S1 and T2 states will cross the lowest triplet state, and the S1 → T intersystem crossing happens in a multi-state quasi-degeneracy region S1/T2,3/T1 and is accelerated by selenium-substitution. The present study reveals the influence of both the chalcogen substitution element and initial spectroscopic state on the excited-state relaxation mechanism of nucleobase photosensitizers and also highlights the important role of multi-state quasi-degeneracy in mediating the complex relaxation process. These theoretical results provide additional insights into the intrinsic photophysics of nucleobase-based photosensitizers and are helpful for designing novel photo-sensitizers for real applications.

Cloning, prokaryotic expression and polyclonal antibody preparation of HCCR: a new biomarker for hepatocellular carcinoma / 中华肝脏病杂志

<p><b>OBJECTIVES</b>To construct a prokaryotic plasmid expressing truncated human cervical cancer oncogene (HCCR-1(167-360)), to express and purify the recombinant protein, and to develop the polyclonal antibody against HCCR.</p><p><b>METHODS</b>HCCR-1(167-360) was amplified by RT-PCR from HepG2 cells and cloned into vector pRSET-B, then expressed in E.coli BL21(DE3) pLysS, which was induced by IPTG. The recombinant protein was purified using Ni-NTA spin column and acrylamide gel electrophoresis. A polyclonal antibody was developed by immunizing BALB/c mice with the purified recombinant protein, and their sensitivity and specificity were tested using enzyme-linked immunosorbent assay, immunohistochemical staining and Western blot analysis.</p><p><b>RESULTS</b>Recombinant plasmid expressing truncated HCCR-1167-360 was constructed. A protein of 2.70 x 10(4) was successfully expressed and purified. High titer polyclonal antibody with a high specificity was obtained by immunizing BALB/c mice with the purified recombinant protein.</p><p><b>CONCLUSIONS</b>The truncated recombinant HCCR-1(167-360) developed in this study is highly purified and shows strong antigenecity; the polyclonal antibody against this HCCR protein was generated by regular immunization method, showing both high sensitivity and specificity. The protein and the antibody can be used for further clinical examination and research of HCCR.</p>