RCSB PDB Newsletter
Number 27 -- Fall 2005

Published quarterly by the
Research Collaboratory for Structural Bioinformatics
Protein Data Bank

Weekly RCSB PDB news is available online at
www.rcsb.org/pdb/latest_news.html.

Links to RCSB PDB newsletters are available at
www.rcsb.org/pdb/newsletter.html.

To change your subscription options, please visit
lists.sdsc.edu/mailman/listinfo.cgi/rcsb-news.
-----------------------------------------
TABLE OF CONTENTS

Message from the RCSB PDB

Data Deposition and Processing
     PDB FOCUS: Releasing HOLD and HPUB structures
     PDB FOCUS: Tips for depositing multiple structures with ADIT
     PDB Deposition statistics

Data Query, Reporting, and Access
     PDB FOCUS: Beta FTP site organized by experimental type
     Website statistics
     Data distribution on DVD

Outreach and Education
     RCSB PDB at IUCr: wwPDB booth, presentations, and more
     mmCIF articles published 
     Molecule of the Month features available as individual PDFS

Community Focus: William L. Duax, International Union of
Crystallography and Hauptman-Woodward Medical Research Institute

PDB Education Corner: Miriam Rossi, Vassar College

PDB Molecules of the Quarter

RCSB PDB Job Listings
Statement of Support
RCSB PDB Leadership Team
Snapshot


--------------------------------------------
MESSAGE FROM THE RCSB PDB

To provide a powerful portal for studying the structures of biological
macromolecules and their relationships to sequence, function, and
disease, the RCSB has enhanced and revised the RCSB web and FTP sites.

We encourage you to test and review http://pdbbeta.rcsb.org and
ftp://ftpbeta.rcsb.org before these resources replace the versions
currently in production at www.pdb.org and ftp.rcsb.org on January 1,
2006.

The enhanced web design offers improved navigation for easily locating
the resources and tools offered by the RCSB PDB.  An always-present
left hand menu makes features and resources related to structural
genomics, education, and software easily attainable.

The search tab offers different ways of accessing the RCSB PDB
database, including a new method for "browsing" through structures
grouped in categories related to disease, molecular function,
biochemical process, or cellular location.

The reengineered database is based upon the PDB data that has been
remediated and standardized.  Tools to examine these data include:
improved ligand searching; a clear distinction between the reported
primary and derived data; and the integration of external data
resources currently not available on the production site.

A searchable help system with a glossary and user guide provides
detailed information for accessing the website, database, and for
understanding PDB data.  A narrated presentation in Flash is linked
from the beta site homepage to guide users through searching,
navigating, generating reports, visualizing structures, and browsing
PDB data.

The structural genomics portal offers target summary reports for each
center, databases that track the progress of protein studies (TargetDB
and PepcDB), and a tool to explore the distributions of functions
found among structural genomics structures, PDB structures, genomes,
and homology models.

Thanks to everyone who has contributed to the development of this
resource through their feedback.  Additional comments should be sent
to betafeedback@rcsb.org.

RCSB PDB Beta Site: http://pdbbeta.rcsb.org/
RCSB PDB Beta FTP Site: ftp://ftpbeta.rcsb.org
Tutorial for using the new site: http://pdbbeta.rcsb.org/pdbstatic/tutorials/tutorial.html

The RCSB PDB

--------------------------------------------
DATA DEPOSITION AND PROCESSING

     PDB FOCUS: RELEASING HOLD AND HPUB STRUCTURES

Structure data can be held for a maximum period of one year between
the deposition and release of any entry, even if the paper associated
with an HPUB structure is still unpublished.

Data can always be released before the paper is published. The
citation information can then be updated at a later date.

When a structure has been on hold for a year, we ask the author to
release or withdraw the structure. Withdrawn entries can be
redeposited at a later time, at which point a new PDB ID will be
issued.

We try to release HPUB files as close to the publication date as
possible. The PDB receives publication dates and citation information
from some journals. For other journals, the PDB scans the literature
for publication information (using the deposited author names and
deposited article title). We also greatly appreciate having citation
information sent to deposit@rcsb.rutgers.edu.

     PDB FOCUS: TIPS FOR DEPOSITING MULTIPLE RELATED STRUCTURES 
     USING ADIT

When depositing many structures that are related to one another, there
are a few ways of making the ADIT deposition process simpler:

 * Structures solved using X-ray crystallography should be prepared
   using pdb_extract before using ADIT. This will minimize manual
   typing and save time during deposition. pdb_extract takes
   information about data collection, phasing, density modification,
   and the final structure refinement from the output files and log
   files produced by the various applications used for structure
   determination. The collected information is organized into a file
   ready for deposition using ADIT. Information duplicated in all
   entries (author name, citation information, protein names, etc.)
   can be compiled into a single text file to run with pdb_extract for
   each entry. After pdb_extract has combined all the available
   information into a single file for each structure, ADIT can be used
   for quick deposition.

 * A similar tool is being developed for structures solved by other
   experimental methods. For these structures, deposit one
   representative structure following the instructions provided at
   deposit.pdb.org. Then write to deposit@rcsb.rutgers.edu to let us
   know about the other related entries. Once the first entry has been
   annotated, processed and finalized, it can be used as a template
   for subsequent depositions. For each structure, replace the
   coordinates and update the information in the header section of the
   PDB file as necessary to prepare the related files for deposition.

 * If the structures have ligands, drugs or inhibitors bound to them,
   please check Ligand Depot and match the 3-letter code in the file
   to the one used in the chemical component dictionary. If the ligand
   is not present in the dictionary, please email detailed information
   (complete chemical name, 2D figure showing connectivity, bond order
   and sterochemistry) along with the RCSB and PDB IDs of associated
   entries to expedite the processing of these files.

     PDB DEPOSITION STATISTICS

As of October 1, 4894 experimentally-determined structures have been
deposited to the PDB archives this year.

The entries were processed by wwPDB team members at RCSB, MSD-EBI, and
PDBj. Of the structures deposited, 69% were deposited with a release
status of HPUB; 17% with REL; and 14% with HOLD.

81% of these entries were determined by X-ray crystallography; 16%
were determined by NMR. 81% were deposited with experimental data. 56%
released the sequence in advance of the structure's release.


--------------------------------------------
DATA QUERY, REPORTING, AND ACCESS

     PDB FOCUS: BETA FTP SITE ORGANIZED BY EXPERIMENTAL TYPE

The RCSB has introduced a new ftp site designed to address the
increasing number and diversity of structure entries. Entries within
ftp://ftpbeta.rcsb.org are organized by the method of structure
determination. This new ftp structure distinguishes entries obtained
from X-ray and neutron diffraction, NMR, electron microscopy, or
theoretical modeling techniques.

Within each structure determination category, there are directories
containing files for entries in mmCIF, PDB, and XML formats;
biological unit files; and the structure factor or restraint
files. Individual entries are stored in a collection of 2-character code
subdirectories corresponding to the middle characters of the 4-character
PDB identifier.

All entries in the new ftp site are compressed using the GNU gzip
utility. 

This beta ftp site is updated weekly in conjunction with the current
ftp site, ftp://ftp.rcsb.org. Both ftp sites will be maintained
through December 2005. After this time, only the new organization will
be supported.

For comments about the beta FTP send mail to betaftp@rcsb.rutgers.edu.


     WEBSITE STATISTICS

Access statistics are given below for the primary RCSB PDB website
at www.pdb.org.

    Daily Average.....Monthly Totals
Month...Hits.....Files....Sites.....KBytes....Files.......Hits
Sep 05..287624..208009...144490..230808396..6032283....8341119
Aug 05..203087..149599....99488..241077817..4487998....6092621
Jul 05..215619..160129...100218..272765261..4803890....6468598


     DATA DISTRIBUTION ON DVD

As of 2005, the PDB archives will be made available as an annual DVD
product. The CD-ROM product has been discontinued.

The PDB has historically distributed coordinate data through the mail;
starting in 1990, the data were produced on CD-ROM. In addition to the
rapid increase in the number and size of structures in the archives,
the number of formats to distribute has also increased (to PDB, mmCIF,
and PDBML/XML). Currently, it would take over 50 disks to distribute
the archives on CD-ROM.

To minimize the difficulty of producing (and keeping up with a large
number of CDs), the RCSB PDB began distributing an incremental set of
data each quarter in April 2003.

Starting in January 2005, ftp://snapshots.rcsb.org/ was created to
hold time-stamped yearly snapshots of the PDB archives. This was done
as part of a wwPDB initiative (wwpdb.org). The first snapshot
directory contains the exact and complete contents of the FTP archives
as it appeared on January 6, 2005. These data, along with data in
XML/PDBML format, were also made available as an 8 DVD release.

To order a DVD set, please email your postal address to
cddvd@rcsb.rutgers.edu. New orders will be filled in the order that
they are received until supplies are exhausted. Please allow several
weeks for delivery.


--------------------------------------------
OUTREACH AND EDUCATION

     RCSB PDB AT IUCR: WWPDB BOOTH, PRESENTATIONS, AND MORE

The new RCSB PDB website, along with tools for deposition, was
demonstrated at this year's XX Congress & General Assembly of the
International Union of Crystallography (IUCr, August 23 - 31 in
Florence, Italy). The exhibit was part of the exhibit stand designed
with wwPDB partners MSD-EBI and PDBj.

Several talks were also presented during the Congress, including lead
annotator Kyle Burkhardt's "Deposition and Validation using RCSB PDB
Tools" as part of the CCP4 Workshop; director Helen M. Berman's "How
the RCSB validates PDB Structures" during the microsymposium Improving
Structures Using Bioinformatics; and software leader Zukang Feng's
"Applications at the RCSB Protein Data Bank" during the COMCIFS Open
Commission Meeting on the Current Status and Future Prospects of CIF.

Helen M. Berman gave an overview of the wwPDB at the Round Table on
Data Mining chaired by Judith L. Flippen-Anderson. wwPDB
representatives Kim Henrick (MSD-EBI), Haruki Nakamura (PDBj), and
Philip E. Bourne (RCSB PDB) then showed how their different interfaces
can be used to mine the data within the PDB archives.

The RCSB PDB Poster Prize was awarded to Sasa Jenko Kokalj for
"Proline isomerisation in stefin B: A crucial step towards amyloid
fibril formation" by Sasa Jenko Kokalj, Gregor Guncar, Eva Zerovnik,
and Dusan Turk (Department of Biochemistry and Molecular Biology,
Jozef Stefan Institute, Ljubljana, Slovenia). The judging committee
was comprised of Maria-Armenia Carrondo (Chair), Carlos Frazao,
Ramakumar Suryanarayanarao, Xiao-Dong Su, Edward Mitchell, and Marius
Jaskolski.


     MMCIF ARTICLES PUBLISHED IN NEW EDITION OF THE INTERNATIONAL
     TABLES FOR CRYSTALLOGRAPHY (VOLUME G)

Several articles describing the macromolecular Crystallographic
Information File format (mmCIF) and how it is used at the RCSB PDB are
in the recently-published International Tables for Crystallography
Volume G: Definition and Exchange of Crystallographic Data.

Included in this reference guide for programmers, data managers, and
crystallographers are in-depth articles that will aid in the design of
interoperable computer applications, including "Classification and use
of macromolecular data", "Macromolecular dictionary (mmCIF)",
"Specification of the Crystallographic Information File", "The Protein
Data Bank exchange data dictionary", "The use of mmCIF architecture
for PDB data management", and "Specification of a relational
Dictionary Definition Language (DDL2)".

This volume was edited by S.R. Hall, and B. McMahon, and published for
the International Union of Crystallography by Springer (Dordrecht, The
Netherlands) in 2005. Ordering information is available at
journals.iucr.org/iucr-top/it/itg/itg.html.


     MOLECULE OF THE MONTH FEATURES AVAILABLE AS INDIVIDUAL PDFS

The Molecule of the Month (MOM) series presents short accounts that
describe selected molecules from the PDB. These online chapters are
now available as downloadable PDFs that can be easily shared, printed,
or incorporated into classroom lessons. Users can download individual
MOM features by going to the Molecule of the Month contents page and
clicking on the PDF link displayed after the molecule title.

Each installment includes an introduction to the structure and
function of the molecule and relates the molecule to human health and
welfare. Suggestions for viewing structures on the RCSB PDB website
and for additional reading are also provided. Produced and illustrated
by David S. Goodsell since 2000, the Molecule of the Month is a proven
resource for the classroom.

Previous MOM features have explored structures such as actin,
collagen, DNA, green fluorescent protein, ribosome, and transfer RNA.


-----------------------------------------
COMMUNITY FOCUS: WILLIAM L. DUAX, INTERNATIONAL UNION OF
CRYSTALLOGRAPHY AND HAUPTMAN-WOODWARD MEDICAL RESEARCH INSTITUTE

Dr. Duax received his Ph.D. in physical chemistry from the University
of Iowa in 1967.  He came to the Hauptman-Woodward Medical Research
Institute in 1968 where he was head of the Molecular Biophysics
Department from 1970-88, Research Director from 1988-93, Executive
Vice President 1993-1999, and is currently H.A. Hauptman Distinguished
Scientist.  He is a Professor of the Department of Structural Biology
at the State University of New York at Buffalo and the Chief Executive
Officer of the American Crystallographic Association.  and President
of the International Union of Crystallography.  He was a Fulbright
Scholar in Yugoslavia in 1987, and received the Distinguished
Scientist award from the Clinical Ligand Assay Society in 1994 and an
Honorary Doctoral Degree from the University of Lodz Poland in 1999.
He recently ended his term as President of the International Union of
Crystallography.

Dr. Duax uses X-ray crystallographic analysis to determine the
structure of biologically active molecules and correlates structures
with biological activity.  Early in his career he determined the
structures of hundreds of steroids, published a two volume Atlas of
Steroid Structure and developed an empirical model for steroid
receptor binding and hormone action, (the A-ring binding/D-ring acting
model) that proved valuable in the design of antiprogestational
agents.  More recently, together with Debashis Ghosh, he began a
series of studies of steroid dehydrogenases. They determined the first
crystal structure of a short chain oxidoreductase (SCOR) enzyme,
elucidated of the molecular mechanism of action of SDHs, the basis for
inhibition of 11beta-HSD by glycyrrhizic acid and the role of licorice in
hypertension.

Recently he has begun combining information from the 3D structures of
SCOR enzymes with sequence analysis of all putative SCOR genes in the
gene bank to predict fold, function, cofactor, and substrate for 6000
genes.  He is also engaged in a genomics project to trace the origin
and evolution of the genetic code and the evolution of the amino acid
composition of proteins.

Q: You were a prolific small molecule crystallographer (with ~250
entries in the Cambridge Structural Database, CSD). Why did you decide
to shift your research efforts to focus on macromolecules?
 
A: There were two main reasons, one scientific and the other
practical. The majority of our structures in the CSD are steroids. We
were trying to understand how subtle changes in the shape and
intermolecular interactions of steroids influenced their control of
sugar metabolism, salt balance, sexual development, and
fertility. Although we were able to develop empirical models for
steroid structure and function, it became clear that we needed the
three-dimensional structures of their protein targets to adequately
test our models. Therefore, we developed collaborations with
biochemists who were isolating steroid hormone receptors and
enzymologists studying the biosynthesis and metabolism of steroids. We
were fortunate that our first protein structure determination was of
an ancient member of the short-chain oxidoreductase (SCOR) enzyme
family. SCORs control the balance of active and inactive steroids
involved in normal biological processes. Using that first structure,
Debashis Ghosh was able to propose a model for the mechanism of action
of the enzyme. This model provided the basis for understanding the
activities of dozens of additional SCORs in the PDB and thousands of
homologous proteins in the Swiss-Prot/TrEMBL databases. The practical
reason for shifting our focus to macromolecules was that we had to go
where the money was. When we published our first steroid structure in
1969, there were only a few hundred crystal structures of organic
compounds in the literature. In the 1960s and 1970s, small molecule
crystallography enjoyed significant support from the US National
Institutes of Health (NIH). Currently, there are over 325,000 entries
in the CSD, and NIH support has gradually shifted to macromolecular
crystallography. Today, the macromolecular crystallographic community
is facing a challenge similar to when small molecule crystallographers
were unwisely relegated to the role of service crystallographers in
the 1980s.
 
Crystallographers are well-equipped to make sense of the mass of data
that the genome project has brought to light. Anticipating yet another
sea change in federal funding, we have begun to utilize the explosion
of macromolecular sequence data in combination with macromolecular
structural data in an effort to try to predict the structure function
relationship and ligand binding of thousands of hypothetical gene
products.
 
Q: As a relatively new user of the RCSB PDB, have you found it easy to
use and beneficial in your current research?
 
A: The PDB is absolutely essential to our current efforts to predict
the structure and function of the 6,000 putative SCOR enzymes in the
Swiss-Prot/TrEMBL databases. I find it very easy to access and use the
PDB. This is all the more remarkable because I am totally incompetent
when it comes to using computers. We use the PDB to examine the
details of a billion years of molecular evolution and interactions
between proteins and their cofactors and substrates in search of
patterns that have predictive power. We also use the PDB to examine
the nature of the interfaces among monomers in multimeric structures
that are often their active forms. These studies give us insight into
protein-protein interactions and allosteric behavior.
 
TargetDB is another reason that the RCSB PDB is critical to our
research program. We use it as a resource for information on the most
recently determined SCOR proteins as well as to identify new
candidates to test predictions based on our proteomic research.
 
Q: The RCSB PDB has been involved in the creation, maintenance, and
extension of the mmCIF dictionary since its commission by the IUCr in
the early 1990s. The collaboration was further strengthened this year
when the IUCr launched Acta Crystallographica Section F for the rapid
publication of communications on structural genomics, protein
structure and crystallization. What is the IUCr's perspective on this
collaboration?
 
A: The collaboration between the RCSB PDB and the IUCr has been
vitally important and extremely productive. One of the IUCr's goals is
to extend the powerful technique of crystallography throughout the
world. The IUCr journals are meant to be international archival
journals for publication of the most accurate structure
determinations. It is also essential to the mission of the IUCr to
make the data available to the world community as economically and
effectively as possible. The fact that the PDB is available to
everyone in the world at no cost makes it an ideal resource for the
IUCr community.
 
Q: You have traveled extensively during your tenure as IUCr
President. Where have you seen the most potential for growth in new
depositions to the PDB?
 
A: The future growth of the field of crystallography with respect to
new structure determinations of all types of matter and the next
generation of crystallographers is in the emerging nations of Latin
America, the Asia-Pacific region, and Africa. Most emerging countries
have indigenous plant, insect, and bacterial species with unique
properties. Studies of the structures in these materials will provide
new leads for rational drug design and disease control. We can already
see the impact of the growth of a crystallographic infrastructure in
these countries in the increased numbers of structure reports in Acta
Crystallographica Section E that are coming from China, Malaysia and
Turkey. Over 50% of the papers submitted to Acta Crystallographica
Section E in 2004 came from China. It is only a matter of time before
we see a similar explosion in macromolecular structure reports from
these countries in Acta Crystallographica Section F.


-----------------------------------------
PDB EDUCATION CORNER: MIRIAM ROSSI, VASSAR COLLEGE

Miriam Rossi has been at Vassar since 1982 after she worked as a
Research Associate at The Institute for Cancer Research of The Fox
Chase Cancer Center in Philadelphia.

She received her Ph.D. at The Johns Hopkins University. Her work is
concerned with the relationship between the structure and function of
molecules, mainly those having biological activity. These include
natural plant products that show anti-tumor activity as well as others
that are active against some of the proteins in HIV. The technique she
uses is single crystal X-ray crystallography, and she is co-author of
a leading text in this area.

She has received grants from the National Science Foundation, the
Petroleum Research Fund of the American Chemical Society, and the
Camille and Henry Dreyfus Foundation.

Besides the U.S., she has taught courses in Australia, Italy, and most
recently under the auspices of the Rotary Foundation, in Chile. Her
work has appeared in the Journal of Medicinal Chemistry, Inorganic
Chemistry, Organometallics, Archives of Biochemistry and Biophysics,
and the Journal of Natural Products, among many others.

Her teaching interests include general chemistry, inorganic chemistry,
and structural chemistry, and she particularly enjoys conducting
research with undergraduates.

This interview about one of her courses will also appear in a Vassar
College website that highlights courses that incorporate information
technology in teaching activities at
http://computing.vassar.edu/news/faculty/facultyfocus/.

Q. What is your Structural Chemistry and Biochemistry course about?
Tell us about its origin, goals and objectives.

A. Today, interdisciplinary research and areas of study are the norm
in the sciences. The borderlines of research in chemistry, biology,
physics, geology are vanishing, and increasingly molecular
interactions and chemical transformations are found to be at the heart
of biology, biochemical and biomedical phenomena as well as
understanding the behavior of new materials, material sciences and
geological sciences. For example, many diseases and their treatment
are molecular in nature and medicinal chemistry and pharmaceutical
companies have large components dedicated to drug design research that
has structural information as its basis.

This course was developed to make students aware that the same
fundamental principles that govern the molecular architecture for
metals and small salt compounds also explain the structures of
macromolecules and molecular assemblies, such as viruses. General
texts in chemistry, biology, geology, biochemistry and solid-state
physics are full of molecular structure representations obtained from
the three-dimensional atomic coordinates determined by X-ray
diffraction. Unfortunately, there is difficulty in interpreting these
spatial arrangements, especially as the structures of increasingly
larger molecules become available. This problem is not new. In 1925,
Sir William Bragg wrote in the Preface to his book, Concerning the
Nature of Things: There are some who think this difficulty is
incurable, and that it is due to the want of some special capacity,
which only a few possess. I am persuaded that this is not the case: we
should have nearly as much difficulty in grasping events in two
dimensions as in three were it not that we can so easily illustrate
our two-dimensional thoughts by pencil and paper. If one can turn over
a model in ones hand, an idea can be seized in a mere fraction of the
time that is required to read about it, and a still smaller fraction
of the time that is required to prepare the description. (Dover
Phoenix Editions)

The goals of this course involve familiarizing students with basic
concepts of molecular structure and geometry, chemical bonding and
intermolecular interactions; to introduce students to X-ray
crystallographic methods for determining molecular structure; how to
read a crystal structure paper; to study the structures of molecules
of chemical and biological interest; interpreting the complex images
that accompany structural papers. The overall aim is to see how the
molecular structure is one of the determinant features responsible for
chemical and/or biological activity. It is an advanced level course
open to chemistry and biochemistry majors or students declaring a
chemistry or biochemistry correlate sequence (frequently called a
minor subject area).

I am able to attain these goals by using different computer programs
and databases that can be accessed in a computer classroom containing
15 desktop computers. An Academic Computing Consultant who is a
science computation specialist maintains this computer classroom; his
presence has ensured the successful outcome of this course.


Q. What were the technologies used and how did they change or enhance
your course?

A. I use two main computer tools: the PDB, a large repository for the
processing and distribution of 3-D biological macromolecular structure
data, and the Cambridge Crystallographic Structural Database (CCSD),
which is a database of bibliographic, chemical and crystallographic
information for organic molecules and organo-metallic compounds. The
CCSD is not freely available, but fortunately the college has a
campus-wide license for it. The RCSB PDB is freely and widely
available on the web.

The addition of these tools has made a huge difference in teaching
this course. For example, the various visualization capabilities
available in the two databases make the content easier to teach, since
many structural features become self-evident when they are viewed. The
ability to manipulate, rotate and edit structures allows instructors
to convey these structural rules that are not easy to visualize or
understand otherwise. While this is true for all three-dimensional
structural data, it is essential for understanding macromolecular
data; the PDB is an indispensable resource to achieve this objective.

Q. How have your students responded to your use of technology?

A. Students are very receptive to acquire information through
interactive and visual experience. I hear students praise the software
all the time; they like being able to see and manipulate molecules; it
is intuitive, easy and fun. Frequently, in courses where the concepts
of molecular shape and chemical properties derived from molecular
shapes are introduced, for example, organic chemistry, students use
model kits as a teaching aid. While this is a useful exercise, being
able to rotate the structure on the screen and see how a molecule
interacts with others is especially valuable. The use of these
structural databases reinforces material that they learn about in
their textbooks. It becomes clear that the connections between atoms
to make molecules and how molecules are grouped together to make
molecular assemblies all have similar foundations. Geometrical details
can be calculated easily and displayed. These resources have made
describing molecular features much easier, and since students can
access the PDB online at anytime students can access information for
problem sets at their convenience.

The use of interactive computer graphics software is especially
indispensable when teaching macromolecular structure. The level of
complexity in macromolecular structure is astounding. Proteins can
have diverse shapes or motifs that make up their final 3-D structure.
It is here that the PDB becomes such a useful teaching tool: it
permits students to look at the complex protein or other large
macromolecular assembly using options that permit a different
perspective by zooming in to a particular site and rotating the
structure. It becomes possible to view the same structural motif in
many proteins, allowing for interesting discussion to take place in
the classroom: the PDB reinforces material that they learn about in
their textbooks (The text I use is Introduction to Protein Structure,
2nd Edition by Branden and Tooze, Garland Publishing). Geometrical
details can be calculated easily and displayed. The Molecule of the
Month feature is outstanding and almost forms the basis for the
macromolecular part of this course; it features an in-depth look at a
collection of well-studied molecules. It provides a well-written
introduction to a molecule, its biological importance, how the
structural features are utilized by the molecule to attain its
function, and highlights the use of common structural motifs by
related compounds. My students use this feature as a starting point in
many of their in-depth analyses that are required for homework
assignments. What I have found is that because the RCSB PDB is easy to
use, students literally can spend hours manipulating these complex
structures. And, every instructor knows that the more time a student
spends on trying to understand course material, the more attracted
they become to the subject.

Every year, I try to shape the course contents taking into account the
particular interests of my students. They really enjoy being able to
use these databases to find and visualize well-known structures they
learn about in other contexts; for example, they can see how toxins
such as cholera or anthrax toxins behave at an atomic level, as well
as the common cold and influenza viruses. Some of the topics we
discuss are how DNA modifies its shape as it interacts with a variety
of proteins; the mathematical description of the morphology of virus
particles, etc. Since students pick a topic for an end-of-the-year
presentation, sometimes I get to see really interesting things
happening in the classroom. I remember that a student who was an Art
History major gave a presentation comparing the structural features
that provide stability to molecules to those that are commonly used
when building macroscopic structures such as bridges or buildings.

Q. What were the challenges you faced when teaching this course?

A. Even though these computer programs are very well built, and easy
to use, there is always a learning curve that students must go
through. Most of them are very quick learners, but with a few one has
to be more patient and guide them through the first couple of
sessions. For example, seeing complex protein structural patterns,
such as the Greek key motif, need to be explained one-on-one. A good
idea would be having an experienced student assistant helping students
during lecture time.


--------------------------------------------
MOLECULES OF THE QUARTER

The Molecule of the Month series explores the functions and
significance of selected biological macromolecules for a general
audience.

The molecules featured this quarter were TATA-Binding Protein,
Neurotrophins, and Cholera Toxin.

The complete Molecule of the Month features are available at
www.rcsb.org/pdb/molecules/molecule_list.html.


-----------------------------------------
STATEMENT OF SUPPORT

The RCSB PDB is supported by funds from the National Science
Foundation, the National Institute of General Medical Sciences, the
Office of Science, Department of Energy, the National Library of
Medicine, the National Cancer Institute, the National Center for
Research Resources, the National Institute of Biomedical Imaging and
Bioengineering, and the National Institute of Neurological Disorders
and Stroke.

The RCSB PDB is managed by two partner sites of the Research
Collaboratory for Structural Bioinformatics:

RUTGERS
Rutgers, The State University of New Jersey
Department of Chemistry and Chemical Biology
610 Taylor Road
Piscataway, NJ 08854-8087

SDSC/UCSD
San Diego Supercomputer Center
University of California, San Diego
9500 Gilman Drive
La Jolla, CA 92093-0537

The overall operation of the PDB is managed by the 
RCSB PDB Leadership Team. Technical and scientific
support is provided by the RCSB PDB Members.

RCSB PDB LEADERSHIP TEAM

Dr. Helen M. Berman - Director
Rutgers University
berman@rcsb.rutgers.edu

Dr. Philip E. Bourne - Co-Director
SDSC/UCSD
bourne@sdsc.edu

Allison Clarke - Operations Coordinator
Rutgers University
aclarke@rcsb.rutgers.edu

Judith L. Flippen-Anderson - Outreach Coordinator
Rutgers University
flippen@rcsb.rutgers.edu

Dr. John Westbrook - Co-Director
Rutgers University
jwest@rcsb.rutgers.edu

A list of current RCSB PDB Team Members is available at 
www.rcsb.org/pdb/rcsb-group.html

The RCSB PDB is a member of the Worldwide PDB (www.wwpdb.org)


-----------------------------------------
SNAPSHOT -- October 1, 2005

32823 released atomic coordinate entries

Molecule Type
29964 proteins, peptides, and viruses
 1504 nucleic acids
 1342 protein/nucleic acid complexes
   13 carbohydrates

Experimental Technique
28040 diffraction and other
 4783 NMR

18200 structure factor files
 2647 NMR restraint files