Race and ancestry in biomedical research: exploring the challenges.

The use of race in biomedical research has, for decades, been a source of social controversy. However, recent events, such as the adoption of racially targeted pharmaceuticals, have raised the profile of the race issue. In addition, we are entering an era in which genomic research is increasingly focused on the nature and extent of human genetic variation, often examined by population, which leads to heightened potential for misunderstandings or misuse of terms concerning genetic variation and race.

From diversity to delivery: the case of the Indian Genome Variation initiative.

India currently has the world's second-largest population along with a fast-growing economy and significant economic disparity. It also continues to experience a high rate of infectious disease and increasingly higher rates of chronic diseases. However, India cannot afford to import expensive technologies and therapeutics nor can it, as an emerging economy, emulate the health-delivery systems of the developed world.

Genomics, public health and developing countries: the case of the Mexican National Institute of Genomic Medicine (INMEGEN).

In 2004, the government of Mexico established the National Institute of Genomic Medicine (INMEGEN), to carry out disease-related genomic studies that will address national health problems and stimulate scientific and technological development by generating new commercial products and services in genomic medicine. Towards this end, INMEGEN is carrying out a large-scale genotyping project to map genomic variation within its own population. The initiative is expected to generate a key resource for local researchers to understand disease susceptibility and variation in drug responses, which will contribute to Mexico's goal of developing public health genomics - a field in which Mexico is proving to be a leader amongst emerging economies.

The next steps for genomic medicine: challenges and opportunities for the developing world.

This is a historical moment on the path to genomic medicine - the point at which theory is about to be translated into practice. We have previously described human genome variation studies taking place in Mexico, India, Thailand, and South Africa. Such investments into science and technology will enable these countries to embark on the path to the medical and health applications of genomics, and to benefit economically.

South Africa: from species cradle to genomic applications.

The South African government is committed to science and technology innovation, to establishing a knowledge-based economy and to harnessing life-sciences research for health and economic development. Given the constraints and the early stage of development of the field as a whole in South Africa, we found an impressive amount of research on human genomic variation in this country. Encouragingly, South Africa is beginning to apply genomics to address local health needs, including HIV and tuberculosis (TB) infections.

Universal health care, genomic medicine and Thailand: investing in today and tomorrow.

One potential outcome of investing in genomic medicine is the provision of tools for creating a more cost-effective health-care system. Partly with this aim in mind, Thailand has launched two genotyping initiatives: the Thai SNP Discovery Project and the Thai Centre for Excellence in Life Sciences Pharmacogenomics Project. Together, these projects will help Thailand understand the genomic diversity of its population and explore the role that this diversity has in drug response and disease susceptibility in its population.

Genomic medicine and developing countries: creating a room of their own.

The notion that developing countries must wait for the developed world to make advances in science and technology that they later import at great cost is being challenged. We have previously argued that developing countries can harness human genetic variation to benefit their populations and economies. Based on our empirical studies of large-scale population genotyping projects in Mexico, India and Thailand, we describe how these resources are being adopted to improve public health and create knowledge-based economies.

Gene expression profiling in a model of D-penicillamine-induced autoimmunity in the Brown Norway rat: predictive value of early signs of danger.

Idiosyncratic drug reactions (IDRs) cause significant morbidity and mortality. In an animal model of IDRs, 50-80% of Brown Norway rats exposed to D-penicillamine develop an autoimmune syndrome after several weeks of treatment. The symptoms of the IDR are similar to that observed in humans who take D-penicillamine.

D-penicillamine-induced autoimmunity in the Brown Norway rat: role for both T and non-T splenocytes in adoptive transfer of tolerance.

The D-penicillamine autoimmune syndrome observed in Brown Norway (BN) rats is similar to an idiosyncratic reaction seen in some patients. We have previously shown that 2 weeks of low dose (5 mg/day) D-penicillamine pretreatment completely prevented all clinical signs of autoimmunity normally observed in 60-80% of rats treated with high dose (20 mg/day) D-penicillamine. We demonstrated that this tolerance is immune-mediated; tolerance to D-penicillamine is long lasting, we can adoptively transfer splenocytes from tolerant rats into slightly irradiated naive syngeneic recipients, and rats exposed to low dose D-penicillamine produce tolerogenic cytokines [Masson, M.

Modulation of D-penicillamine-induced autoimmunity in the Brown Norway rat using pharmacological agents that interfere with arachidonic acid metabolism or synthesis of inducible nitric oxide synthase.

The D-penicillamine-induced autoimmune syndrome observed in Brown Norway (BN) rats is similar to an idiosyncratic reaction seen in some patients. We have previously shown that pretreatment of BN rats with aminoguanidine, an inducible nitric oxide synthase (iNOS) inhibitor, and misoprostol, a prostaglandin E (PGE) analog, completely prevented the development of D-penicillamine-induced autoimmunity. In an effort to further understand the role of arachidonic acid metabolism and iNOS in the pathogenesis of D-penicillamine-induced autoimmunity we had 3 objectives: (1) to test whether aminoguanidine and misoprostol could reverse D-penicillamine-induced autoimmunity; (2) whether BN rats that had previously developed D-penicillamine-induced autoimmunity could be protected on re-challenge with drug by pretreatment with aminoguanidine and misoprostol and (3) whether non-steroidal anti-inflammatory drugs, which inhibit PGE synthesis, would potentiate D-penicillamine-induced autoimmunity.

The danger hypothesis applied to idiosyncratic drug reactions.

Purpose Of Review: Idiosyncratic drug reactions pose a significant clinical threat and hamper drug development. The idiosyncratic nature of these reactions has made mechanistic studies exceedingly difficult, and yet without a better understanding of the mechanisms involved it is unlikely that much progress can be made in dealing with the problem. Several working hypotheses have been used to study these reactions, but none fits all of the characteristics that are observed.

Mapping of determinants required for the function of the HIV-1 env nuclear retention sequence.

Control of HIV-1 RNA processing and transport are critical to the successful replication of the virus. In previous work, we identified a region within the HIV-1 env that is involved in mediating nuclear retention of unspliced viral RNA. To define this sequence further and identify elements required for function, deletion mutagenesis was carried out.