PyDISH: database and analysis tools for heme porphyrin distortion in heme proteins

Heme participates in a wide range of biological functions such as oxygen transport, electron transport, oxygen reduction, transcriptional regulation and so on. While the mechanism of each function has been investigated for many heme proteins, the origin of the diversity of the heme functions is still unclear and a crucial scientific issue. We have constructed a database of heme proteins, named Python-based database and analyzer for DIStortion of Heme porphyrin (PyDISH), which also contains some analysis tools. The aim of PyDISH is to integrate the information on the structures of hemes and heme proteins and the functions of heme proteins. This database will provide the structure–function relationships focusing on heme porphyrin distortion and lead to the elucidation of the origin of the functional diversity of heme proteins. In addition, the insights obtained from the database can be used for the design of protein function. PyDISH contains the structural data of more than 13 000 hemes extracted from the Protein Data Bank, including heme porphyrin distortion, axial ligands coordinating to the heme and the orientation of the propionate sidechains of heme. PyDISH also has information about the protein domains, including Uniprot ID, protein fold by CATH ID, organism, coordination distance and so on. The analytical tools implemented in PyDISH allow users to not only browse and download the data but also analyze the structures of heme porphyrin by using the analytical tools implemented in PyDISH. PyDISH users will be able to utilize the obtained results for the design of protein function. Database URL: http://pydish.bio.info.hiroshima-cu.ac.jp/

CSTDB: A Crop Stress-tolerance Gene and Protein Database Integrated by Convolutional Neural Networks

Numerous studies have shown that many genes and proteins in plants are involved in the regulation of plant resistance to abiotic and biotic stresses. The researches on the stress tolerance of crops are also the focus of many researchers. To provides a reliable platform for collecting and retrieving genetic and protein information related to stress tolerance found in crops, we constructed CSTDB(Crops Stress-tolerance Database), an integrated database that includes stress-tolerance genes and proteins for many crop species. The database was developed based on convolutional neural network technology. It is a web-accessible database that contains detailed information on the stress-tolerance genes and proteins of major crop species. Currently, the database records four major crops containing 1,371 abiotic stress-tolerance genes or proteins, and 207 genes or proteins associated with biotic stress. Each gene and protein has detailed functional information and sequence information, such as stress types, Genbank ID, Pubmed ID, Protein ID, 3D model picture and FASTA files. As a user-friendly browsing tool, this database provides search functions, BALST functions and file download functions. CSTDB can be a valuable resource, which is designed to meet the broad needs of researchers working on crops stress-tolerance experiments. Database URL: http://pcsb.ahau.edu.cn:8080/CSTDB

Regulation of the Drosophila ID protein Extra macrochaetae by proneural dimerization partners

Proneural bHLH proteins are transcriptional regulators of neural fate specification. Extra macrochaetae (Emc) forms inactive heterodimers with both proneural bHLH proteins and their bHLH partners (represented in Drosophila by Daughterless). It is generally thought that varying levels of Emc define a prepattern that determines where proneural bHLH genes can be effective. We report that instead it is the bHLH proteins that determine the pattern of Emc levels. Daughterless level sets Emc protein levels in most cells, apparently by stabilizing Emc in heterodimers. Emc is destabilized in proneural regions by local competition for heterodimer formation by proneural bHLH proteins including Atonal or AS-C proteins. Reflecting this post-translational control through protein stability, uniform emc transcription is sufficient for almost normal patterns of neurogenesis. Protein stability regulated by exchanges between bHLH protein dimers could be a feature of bHLH-mediated developmental events.

Abstract 393: The Intercalated Disc Protein Myozap: A Novel Player in Cardiac Proteinopathy

Background: A growing number of cardiac muscle diseases are characterized by depositions of misfolded proteins, including cardiac amyloidosis and desmin-releated cardiomyopathy (DRM). The continued presence and chronic accumulation of misfolded or unfolded proteins can lead to aggregation and/or the formation of soluble peptides that are proteotoxic. This in turn leads to compromised protein quality control and precipitates a downward spiral of the cell’s ability to maintain homeostasis and may eventually result in cell death. We recently identified massive protein aggregates in the hearts of transgenic mice overexpressing the intercalated disc (ID) protein myozap (Myozap-tg). We now sought to investigate the precise composition of these aggregates and the role of Myozap in other proteinopathies such as DRM. Methods and Results: We employed multi-dimensional proteomics, transcriptomics, confocal microscopy, and molecular biology approaches to decipher the underlying causes and consequences of protein aggregate formation in Myozap-tg mice. Transcriptome profiling of these mice revealed striking upregulation of autophagy, protein synthesis, and pro-inflammatory pathways, whereas protein degradation pathways were down-regulated. Surprisingly, proteomics analyses revealed Desmin and α-crystallin B (CryAB) as the major constituents of the aggregates, which was further validated by confocal microscopy. Moreover, we identified the presence of toxic preamyloid oligomers in Myozap-tg mouse hearts, a hallmark in many protein aggregation-based diseases including DRM. Most interestingly, we also observed co-localization of Myozap with protein aggregates observed in both transgenic mouse hearts overexpressing mutant Desmin (D7) and mutant CryAB (R120G), as well as in human DRM patients. Conclusion: The present study implies a new role for Myozap, which was previously reported to affect cardiac SRF signaling: (1) Myozap accumulates in various forms of experimental and human protein aggregation cardiomyopathy, suggesting involvement in protein homoestasis. (2) The fact that Myozap is now the third ID protein (after desmin and CryAB) to cause cardiac proteinopathy points to a general role of the ID in its molecular pathogenesis.