GO BACK GO ON TO INDEX OTHER PART

his past year, ground was broken for the construction of the Human Genome Laboratory, which will for the first time bring together in one facility all of the various research teams that make up Berkeley Lab's Human Genome Center. The new facility will be three stories high and have an area of 44,000 gross square feet. It is expected to cost $24.7 million and construction should be completed in 1997. Until they take occupancy, HGC researchers will continue their efforts to construct high-resolution genetic maps and develop new technologies that will help bring the HGP to a successful and speedy conclusion. Thanks to the film Jurassic Park, the whole world has learned that PCR-the polymerase chain reaction-is the method by which scientists replicate millions of copies of a DNA fragment. In addition to its growing role in forensic analysis, the PCR technique is essential to all genetic research, including the genome project. In 1995, Berkeley Lab scientists and engineers at the Human Genome Center announced the development of an improved type of apparatus, called a "rapid thermal cycler," that can cut in half the time required to perform PCR. A next-generation rapid thermal cycler, in its final stages of development, will be even faster and could lead to the complete automation of the PCR process-a step most HGP researchers say is critical.

Not all diseases are genetic in origin. Many of the worst are caused by viruses and retroviruses, the most notorious of which is HIV. A retrovirus is a protein-coated packet of RNA (ribonucleic acid) that requires the chemicals of a host cell to make viral DNA and proteins from its RNA genome. When a retrovirus invades a cell it synthesizes enzymes that transform the host into a virus replication factory. A major handicap in the medical fight against retroviruses has been a lack of information on the mechanism by which they are able to replicate within host cells. Berkeley Lab scientists, however, have succeeded in producing the first three-dimensional image of an RNA structure crucial to the mechanism. The structure, a double looped strand of RNA that forms what is called a "pseudoknot," was revealed to contain a bend in its shape that may serve as the site where key host proteins interact. Armed with this knowledge, pharmaceutical researchers can now work to design drugs that fight retroviruses by binding to the pseudoknot at this site and blocking these interactions. RNA is the workhorse for the entire genetic world, not just retroviruses. It transcribes the coded instructions of DNA and assembles amino acids into proteins accordingly. Biologists know that RNA can fold back on itself and assume a variety of complex "secondary" shapes to carry out its myriad biological tasks. As was the case with retroviruses, however, there has been little or no detailed information on the various forms these critical secondary RNA structures take. Again, Berkeley Lab scientists have been pushing the knowledge envelope. Working with x-ray crystallography, a technology that traditionally has only been used to determine the shapes of protein structures, they have produced some of the clearest images ever obtained of RNA secondary structures. These images revealed that uracil, one of the four types of nitrogenous "bases" that represent the letters of the genetic code, can pair off with any other letter, including itself. This not only contradicts the exclusive two-letter base-pairing pattern in DNA, it helps explain why RNA is so flexible and why, unlike DNA which has only one form (the double helix), it can take on so many different shapes. The images and the information they have yielded have been made available to scientists throughout the country. With this knowledge, it might soon be possible to study, and possibly control, the functions of secondary RNA structures, a capability that would have enormous ramifications for the field of medicine.

Use the scissors-icon to see the prior part of this document.
GO BACK GO ON TO INDEX OTHER PART