The changing world of modern cell biology

Change is always ambiguous. There is the enticing prospect of novelty and better times ahead, but at the same time the concern of losing the good of the past. It is with these sentiments that I take over as the Editor-in-Chief from Ira Mellman who for a decade has cleverly and effectively lead the JCB. During this time he directed and oversaw an extensive modernization of the journal and guided it through dramatic changes in the publishing world. Ira lead the journal with unyielding dedication and enthusiasm and we in the cell biology community must thank him profoundly for his service. It is his work, together with the invaluable contribution of the best editorial board and the most dedicated professional editorial staff in the scientific publishing business, that allows me to now take over the stewardship of the JCB with a tremendous sense of excitement and determination to continue and expand the JCB's role as the leading journal in the cell biology community and as a trendsetter in the rapidly changing world of modern cell biology

Physiological importance of RNA and protein mobility in the cell nucleus

Trafficking of proteins and RNAs is essential for cellular function and homeostasis. While it has long been appreciated that proteins and RNAs move within cells, only recently has it become possible to visualize trafficking events in vivo. Analysis of protein and RNA motion within the cell nucleus have been particularly intriguing as they have revealed an unanticipated degree of dynamics within the organelle. These methods have revealed that the intranuclear trafficking occurs largely by energy-independent mechanisms and is driven by diffusion. RNA molecules and non-DNA binding proteins undergo constrained diffusion, largely limited by the spatial constraint imposed by chromatin, and chromatin binding proteins move by a stop-and-go mechanism where their free diffusion is interrupted by random association with the chromatin fiber. The ability and mode of motion of proteins and RNAs has implications for how they find nuclear targets on chromatin and in nuclear subcompartments and how macromolecular complexes are assembled in vivo. Most importantly, the dynamic nature of proteins and RNAs is emerging as a means to control physiological cellular responses and pathways

The concept of self-organization in cellular architecture

In vivo microscopy has recently revealed the dynamic nature of many cellular organelles. The dynamic properties of several cellular structures are consistent with a role for self-organization in their formation, maintenance, and function; therefore, self-organization might be a general principle in cellular organization

New Tools for JCB

New technologies and approaches in cell biology research necessitate new venues for information sharing and publication. JCB continues its support of innovation in publishing with the launch of Tools, a new article type for the description of methods and high-throughput datasets, and of a new interface for the JCB DataViewer for hosting high-content screening datasets in their entirety

Locus-specific and activity-independent gene repositioning during early tumorigenesis

The mammalian genome is highly organized within the cell nucleus. The nuclear position of many genes and genomic regions changes during physiological processes such as proliferation, differentiation, and disease. It is unclear whether disease-associated positioning changes occur specifically or are part of more global genome reorganization events. Here, we have analyzed the spatial position of a defined set of cancer-associated genes in an established mammary epithelial three-dimensional cell culture model of the early stages of breast cancer. We find that the genome is globally reorganized during normal and tumorigenic epithelial differentiation. Systematic mapping of changes in spatial positioning of cancer-associated genes reveals gene-specific positioning behavior and we identify several genes that are specifically repositioned during tumorigenesis. Alterations of spatial positioning patterns during differentiation and tumorigenesis were unrelated to gene activity. Our results demonstrate the existence of activity-independent genome repositioning events in the early stages of tumor formation