The wwPDB validation reports provided in the OneDep system now have additional validation for electron microscopy (EM) maps to help users identify potential discrepancies in their data.
The updated wwPDB validation reports in the OneDep system now incorporate an extensive EM map validation process, integrating a range of established validation methods for EM data previously available on the EMDB pages. Initially, this additional EM validation is only provided to depositors in the OneDep system, however in future will be provided for entries throughout the PDB and EMDB archives.
The process includes an analysis of the fit of the PDB model to the EMDB map, represented at an amino acid level on the residue-property plots and globally by a visual overlay of the map and model (see below images). FSC curves are also included to compare reported and estimated resolution, where either half maps or FSC data was uploaded.
The additional EM validation also includes various graphics for visual inspection of the data. Included in the reports are images of orthogonal projections, central slices, mask visualisation, and more, allowing for inspection of details in the map and identification of artifacts. A statistical analysis of the EM map volume is also provided, including graphs of map density distribution, volume estimate by contour, and rotationally averaged power spectrum, providing more thorough analysis of the EM volume.
These changes should help both depositors and users to identify potential errors in EM data and give more clarity about potential limitations of the data in both the PDB and EMDB.
If you have any questions or queries about wwPDB validation, then please contact us at email@example.com.
[ wwPDB News ]
The wwPDB partners are pleased to announce an improved mechanism for the resolution of digital object identifiers (DOIs) associated with released PDB entries. We have launched new wwPDB landing web-pages for each released PDB entry. These pages present basic information about the corresponding PDB structure, offer the model coordinate, experimental data and validation file downloads from the wwPDB FTP area, and, importantly, provide links to all the wwPDB partner websites that serve further advanced information about PDB structures. For an example, please navigate to the landing page for one of recently released entries in the PDB archive https://doi.org/10.2210/pdb6qw9/pdb. This development represents a significant improvement over the previous mechanism, where DOIs would resolve to a PDB-formatted file.
We encourage the scientific journals to make use of these pages and the DOIs issued for each PDB entry by linking to them from the online versions of papers where PDB entries are described or mentioned. We have also taken this opportunity to update the metadata that is associated with each PDB DOI, so that this information can be mined directly from the API offered by our DOI provider (CrossRef).
We would also like to draw the scientific community's attention to the new style of PDB accessions that are being gradually introduced, in preparation for when the supply of the familiar four character codes will be exhausted. The new accessions start with a prefix "PDB_" and contain further eight alphanumeric characters, with the last four characters identical to the familiar four-character codes.
[ wwPDB News ]
On 24th Sep, we will hold a luncheon seminar at the 57th Annual Meeting of the Biophysical Society of Japan in Miyazaki. Details are the following:
Registration at the annual meeting website is necessary. The application period is from 27th Aug 10:00 to 29th Aug 16:00 (JST). The participants are decided by drawing.
* A "Seminar Numbered Ticket" distribution desk will be set up from around 08:10 to 10:00 on the morning of the day, and lunch will be distributed to the first 10 out of the lottery members by the annual secretariat staff. If you would like to participate without lunch, please inquire about admission at the venue.
We'll exhibit a booth at the 29th Science Festa Osaka, which is a scientific event for young people. The exhibition day of our booth is only on 8/18 (Sun).
We are going to exhibit the following menus:
We are pleased to announce the availability of PDB versioning, allowing depositors to update their entries while retaining the same PDB accession code.
Depositors can now submit new coordinates for existing entries. Initially, this is limited to PDB entries that were submitted via the OneDep system, which was introduced in 2014. We plan to extend this functionality to entries deposited in the legacy systems (ADIT and Autodep) in future, and will announce a timeline for this in due course.
Requests should be initiated using the OneDep communication panel within the deposition session for the entry in question. Once submitted, the revised model will be processed by wwPDB biocurators and a new version released. Versioning of PDB entries will be limited to changes in the coordinate files, with no changes permitted to the deposited experimental data. PDB versioning will be limited to one replacement per PDB entry per year, and three entries per Principal Investigator per year.
The most recent version of the entry will be available in the main PDB archive FTP (ftp.pdbj.org [PDBj]/ ftp.wwpdb.org [wwPDB]). All major versions of a PDB structure will be retained in the versioned FTP archive (ftp-versioned.pdbj.org [PDBj]/ ftp-versioned.wwpdb.org [wwPDB]) - more information can be found on the wwPDB website. The structure of the versioned FTP archive has been built allowing for future extension of the PDB code format. PDB entry 1abc would therefore be found in the folder pdb_00001abc.
Changes made to entries during versioning are considered to be either “major” or “minor”. Updates to atomic coordinates, polymer sequence, or chemical description trigger a major version increment, while changes to any other categories are indicated as “minor”. Changes introduced are recorded in the PDBx/mmCIF audit categories.
If you have any further queries regarding the process of PDB versioning, please contact the wwPDB at firstname.lastname@example.org.
[ wwPDB News ]
From today, July 1st 2019, submission of PDBx/mmCIF format files for crystallographic depositions to the PDB is mandatory.
PDBx/mmCIF is now the only format accepted for deposition of PDB structures resulting from macromolecular crystallography (MX), including X-ray, neutron, fiber, and electron diffraction methods via OneDep. The deposition of PDBx/mmCIF format files will improve the efficiency of the deposition process and enhance validation through capture of the more extensive experimental metadata supported by PDBx/mmCIF, compared to the legacy PDB format. PDB entries with 100,000 or more atoms, and those with multiple character chain IDs had no longer been supported by the legacy PDB format. In addition, by 2021, we anticipate the PDB Chemical Component Identifier will need to be extended beyond three characters, which will necessarily result in full retirement of files in the PDB Core Archive that utilize the legacy PDB format.
Refmac, Phenix.refine, and Buster programs can now output PDBx/mmCIF formatted files. For users of other structure determination/refinement software packages, the wwPDB provides stand-alone and web-based tools to convert legacy PDB format files into PDBx/mmCIF format: pdb_extract and MAXIT. More information on outputting and preparing PDBx/mmCIF format files for deposition can be found on the wwPDB website.
The PDBx/mmCIF Working Group has committed to the PDBx/mmCIF data model. PDBx/mmCIF is also supported by visualization software applications, including Jmol/JSMol, Chimera, OpenRasMol, CCP4MG, COOT, PyMOL, VMD, Molmil, LiteMol, Mol* and NGL. In addition, other data resources, such as the Protein Model Portal and SASBDB, have adopted and extended the PDBx/mmCIF framework for data representation.
For any further questions regarding deposition please contact the wwPDB on email@example.com.
[ wwPDB News ]
Our recent update to the wwPDB validation reports provides much clearer validation information for ligands.
We now include 2-dimensional diagrams of ligands, highlighting geometric validation criteria and, for structures determined by crystallography, 3-dimensional views of electron density.
We also provide calculated electron density map coefficients which were used to generate the analysis in the validation reports.
We have collaborated with Global Phasing Ltd to integrate the ligand visualization from buster-report into the wwPDB validation report, as recommended by the wwPDB/CCDC/D3R Ligand Validation Workshop. The ligand visualization will be available for ligands that have been designated as "Ligand of Interest" by the depositor and ligands with a molecular weight greater than 250 Daltons that have outliers.
The following ligand instance of NAP was chosen intentionally as a representative of sub-optimal quality in both the ligand model and its agreement with the X-ray data.
Geometric analysis provided by CCDC Mogul will be highlighted on a 2D diagram of the ligand, as shown below.
In addition to geometric validation for ligands, for X-ray diffraction PDB entries the wwPDB validation report also presents images displaying the ligand and the surrounding electron density map.
We are now providing depositors with electron density map coefficient files (2mFo-DFc and mFo-DFc) from the wwPDB validation pipeline alongside the wwPDB validation report. The electron density map coefficients generated for wwPDB validation reports will be made available to end users in the PDB archive as new entries are released and for existing entries when validation reports for the PDB archive are recalculated.
We hope that these changes to the wwPDB validation pipeline will help depositors to interpret the validation information provided for PDB entries more easily. If you have any queries, please contact the wwPDB at firstname.lastname@example.org.
[ wwPDB News ]
All of us at wwPDB were deeply saddened to hear of the recent passing of Prof. Michael G. Rossmann and our condolences go out to his family and friends at this time. Michael contributed so much to the field of structural biology and was a great supporter of the wwPDB and our activities. Here we would like to share our own tribute to Michael and his contribution to the PDB archiving efforts.
Michael has had an esteemed structural biology career, with over 300 structures to his name in the PDB, spanning from 1977 through to 2019. He also helped to develop the molecular replacement technique, enabling phasing of data in X-ray crystallography, which has been used for structure determination of around 100,000 PDB entries to date. One of Michael's key discoveries is of the Rossmann fold, a structural motif commonly found in enzymes that bind to dinucleotide cofactors. It's importance is highlighted by the fact that around 20,000 structures in the PDB contain a Rossmann fold motif, another lasting legacy of his work within the PDB archive.
Michael also made huge contributions to the field of virology, with hundreds of his virus structures archived in the PDB. This includes the first structure determined of the human rhinovirus, otherwise known as the common cold. His work has significantly improved the knowledge of virus structure and function, supporting development of new therapeutics to treat and prevent viral infections.
Michael was a member of the wwPDB advisory committee for four years, serving on the board from 2009 to 2012, and was also involved in advisory committees for RCSB PDB and EMDataBank. During this time, he provided much advice and guidance to the wwPDB, helping to shape the archiving activities during this time and into the future. Helen Berman, former director of the RCSB Protein Data Bank, highlights how Michael "was an active supporter of the Protein Data Bank from its inception in the early 1970s", while Haruki Nakamura, former head of Protein Data Bank Japan (PDBj), speaks of "always being impressed by his thoughtful comments about the activities of the wwPDB." Haruki adds: "Michael understood the importance of archiving raw experimental data and he had promoted 'data science' for many years."
Gerard Kleywegt, former head of Protein Data Bank in Europe (PDBe), pays tribute to Michael as a person, describing him as "a dynamo, with an enormous zest for life and science who got along with almost everybody." Gerard also emphasises how, even in recent months, "he was still collecting data himself" and recalls Michael's dismay at a grant funding rejection and how "he simply could not understand how that was possible as it was obviously solid science."
We are indebted to Michael for his help and support to the wwPDB and to the structural biology community as a whole. As Helen Berman puts it: "Michael was truly unique in his contributions to structural biology and we will be forever grateful for all he did."
[ wwPDB News ]
自2019年7月1日开始，PDB的晶体学结构数据登记将限定使用PDBx / mmCIF的格式文件。
自2019年7月1日，通过OneDep 登记大分子晶体学（MX）解析的晶体结构，包括X光、中子、纤维衍射和电子衍射法，PDBx / mmCIF将是PDB唯一接受的文件格式。与以往的PDB格式相比，使用PDBx / mmCIF格式文件将改善数据登记效率，并且更完整的记录实验数据以有益于来强化数据验证。同时，以往的PDB格式文件不支持含有100,000以上原子的结构数据以及多个字符的分子链ID。此外，到2021年前，预期PDB的化合物代码将需要扩充到超过三个字符，这必然导致以往的PDB格式文件从PDB核心档案中完全退役。
PDBx / mmCIF工作团队致力于开发PDBx / mmCIF数据模型。各种结构显示应用软件也支持 PDBx / mmCIF，包括Jmol / JSMol、Molmil、Chimera、OpenRasMol、CCP4MG、COOT、PyMOL、VMD、MolMil和NGL。此外，其他数据资源（如Protein Model Portal和SASBDB）已采用并扩展PDBx / mmCIF格式框架，进行数据表现。
[ wwPDB新闻 ]