Wen-chang Lin

Human RegIV Protein Adopts A Typical C-Type Lectin Fold But Binds Mannan With Two Calcium-Independent Sites

Human RegIV protein, which contains a sequence motif homologous to calcium-dependent (C-type) lectin-like domain, is highly expressed in mucosa cells of the gastrointestinal tract during pathogen infection and carcinogenesis and may be applied in both diagnosis and treatment of gastric and colon cancers. Here, we provide evidence that, unlike other C-type lectins, human RegIV binds to polysaccharides, mannan, and heparin in the absence of calcium. To elucidate the structural basis for carbohydrate recognition by NMR, we generated the mutant with Pro91 replaced by Ser (hRegIV-P91S) and showed that the structural property and carbohydrate binding ability of hRegIV-P91S are almost identical with those of wild-type protein. The solution structure of hRegIV-P91S was determined, showing that it adopts a typical fold of C-type lectin. Based on the chemical shift perturbations of amide resonances, two calcium-independent mannan-binding sites were proposed. One site is similar to the calcium-independent sugar-binding site on human RegIII and Langerin. Interestingly, the other site is adjacent to the conserved calcium-dependent site at position Ca-2 of typical C-type lectins. Moreover, model-free analysis of (15)N relaxation parameters and simplified Carr-Purcell-Meiboom-Gill relaxation dispersion experiments showed that a slow microsecond-to-millisecond time-scale backbone motion is involved in mannan binding by this site, suggesting a potential role for specific carbohydrate recognition. Our findings shed light on the sugar-binding mode of Reg family proteins, and we postulate that Reg family proteins evolved to bind sugar without calcium to keep the carbohydrate recognition activity under low-pH environments in the gastrointestinal tract.

Human pancreatitis-associated protein forms fibrillar aggregates with a native-like conformation.

Human pancreatitis-associated protein was identified in pathognomonic lesions of Alzheimer disease, a disease characterized by the presence of filamentous protein aggregates. Here, we showed that at physiological pH, human pancreatitis-associated protein forms non-Congo Red-binding, proteinase K-resistant fibrillar aggregates with diameters from 6 up to as large as 68 nm. Interestingly, circular dichroism and Fourier transform infrared spectra showed that, unlike typical amyloid fibrils, which have a cross-β-sheet structure, these aggregates have a very similar secondary structure to that of the native protein, which is composed of two α-helices and eight β-strands, as determined by NMR techniques. Surface structure analysis showed that the positively charged and negatively charged residues were clustered on opposite sides, and strong electrostatic interactions between molecules were therefore very likely, which was confirmed by cross-linking experiments. In addition, several hydrophobic residues were found to constitute a continuous hydrophobic surface. These results and protein aggregation prediction using the TANGO algorithm led us to synthesize peptide Thr84 to Ser116, which, very interestingly, was found to form amyloid-like fibrils with a cross-β structure. Thus, our data suggested that human pancreatitis-associated protein fibrillization is initiated by protein aggregation primarily because of electrostatic interactions, and the loop from residues 84 to 116 may play an important role in the formation of fibrillar aggregates with a native-like conformation.

An efficient strategy to identify early TPA-responsive genes during differentiation of HL-60 cells.

We have adopted a special experimental strategy to identify early responsive genes during 12-O-tetradecanoylphorbol-13-acetate (TPA)-induced macrophage-like differentiation of human myeloid leukemia cells (HL-60). This was performed in cells that were synchronized by nocodazole and treated with TPA in the presence of a protein synthesis inhibitor, cycloheximide, to prevent activation of secondary targets and therefore increase the probability of early transcripts in total RNA pool. The expression alteration was analyzed by microarray and the selection criteria of candidate genes were adjusted by real-time PCR validation to increase its reliability. Finally, 56 genes were identified as early TPA-responsive genes in this multiscreening step approach. Furthermore, upregulation of three candidate genes (NFIL3, SKIL, and JMJD3) was shown to be dosage and time dependent with TPA treatment and was found to be directly regulated by TPA through PKC-dependent signaling. These results revealed that our screenings provide a useful and efficient approach to identify early TPA-responsive genes and these genes might involve the regulation of TPA-induced differentiation program of HL-60 cells as primary

Identification of the human crooked neck gene by comparative gene identification.

Drosophila melanogaster serves as a useful model organism for functional genomic studies, and its genome project was recently completed. We previously described a comparative-gene-identification approach to assist human ortholog gene identification that involves applying an entire proteome as an alignment template. Analysis of the available 14100 Drosophila protein sequences revealed that 37% of them (5228 sequences) might lead to discoveries of novel human genes. Upon further database interrogations, we found several putative full-length human gene transcripts, including the human crooked neck (crn) gene. Based on sequence gap-closure experiments using reverse transcriptase-polymerase chain reaction as well as bioinformatic analysis, we found that the assembled human cDNA contig of crooked neck gene was at least 3903 base pairs in length with alternative splicing variations which encoded mainly for a 687-amino-acid residue protein. The human crooked neck gene was located on chromosome 20 with at least 15 exons. The unique features of the 16 copies of the tetratrico peptide repeat (TPR) motif were conserved in the yeast, fly and human crooked neck orthologous proteins, which were important for spliceosome assembly in cells.

Functional Variants/Non-synonymous cSNP Discovery by the CGI Bioinformatic Tool

Non-synonymous cSNPs that occurred in the protein-coding region could potentially alter the amino acid composition and thus the functionality of gene product. Protein variants generated by these non-synonymous cSNPs are thought to be responsible for the diversity of human population and the cause of human diseases associated with inheritance. It is essential to identify these non-synonymous cSNPs/functional variants for functional genomic studies. In addition to direct genome sequencing methods, dbEST has been used for SNP discovery due to its rich information of millions ESTs. Previous SNP discovery methods from dbEST needed to include many ESTs per cluster, which greatly reduce the effectiveness of dbEST. Such approaches would be useful in identifying SNPs for polymorphic markers. We would like to identify these sequence variations as either disease association mutations or functional variants. Therefore, it is necessary to use alternative bioinformatic tools to extract these low frequency functional variants. We have used our CGI bioinformatic tools to data-mining functional variants from ESTs, especially low frequency non-synonymous cSNPs. We have established the CGI tools for comparative genomic studies in identifying novel human genes. With 9848 human reference protein as starting alignment scaffolds and 2.2 million human ESTs, we have now identified more than 50,000 potential functional variants. In addition, our approach can be used to validate and correct amino acid sequences of human reference proteins.