Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain
the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in
Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles
and JavaScript.
Studies of schizophrenia have been plagued by shortcomings such as weak genetic association with disease, inadequate animal models and limited replication of gene expression findings. Future success may lie not in overcoming any one of these limitations but in a broad approach strengthening the evidence in each area. Using such an approach, neuroscientists have uncovered a new gene behind the disease (pages 509–518).
The immune response goes haywire during sepsis, a deadly condition triggered by infection. Richard S. Hotchkiss and his colleagues take the focus off of the prevailing view that the key aspect of this response is an exuberant inflammatory reaction. They assess recent human studies bolstering the notion that immunosuppression is also a major contributor to the disease. Many people with sepsis succumb to cardiac dysfunction, a process examined by Peter Ward. He showcases the factors that cause cardiomyocyte contractility to wane during the disease.
Not all financial interests in drug discovery are detrimental, and many are essential for its success. But focusing on perceived conflicts of interest may cause true scientific corruption to go unnoticed.
After an increase in dietary salt, the excess sodium is stored under the skin—stimulating lymphatic growth through the activity of macrophages (pages 545–552). The findings should recast thinking about how blood pressure is regulated.
Current attempts to block angiogenesis during cancer and other diseases are limited partly by their effects on normal angiogenic processes. Could a more targeted approach emerge from the identification of a factor required for pathological angiogenesis under conditions of hypoxia (pages 553–558)?