Elucidating mechanistic principles underpinning eukaryotic translation initiation using quantitative fluorescence methods.

Eukaryotic translation initiation is an intricate process involving at least 11 formally classified eIFs (eukaryotic initiation factors), which, together with the ribosome, comprise one of the largest molecular machines in the cell. Studying such huge macromolecular complexes presents many challenges which cannot readily be overcome by traditional molecular and structural methods. Increasingly, novel quantitative techniques are being used to further dissect such complex assembly pathways.

Changes in the morphology and lability of lysosomal subpopulations in caerulein-induced acute pancreatitis.

Background And Aims: Lysosomes play an important role in acute pancreatitis (AP). Here we developed a method for the isolation of lysosome subpopulations from rat pancreas and assessed the stability of lysosomal membranes.

Methods: AP was induced by four subcutaneous injections of 20 μg caerulein/kg body weight at hourly intervals.

The extracellular linker of pro-neuregulin-alpha2c is required for efficient sorting and juxtacrine function.

The neuregulins (NRGs) play important roles in animal physiology, and their disregulation has been linked to diseases such as cancer or schizophrenia. The NRGs may be produced as transmembrane proteins (proNRGs), even though they lack an N-terminal signal sequence. This raises the question of how NRGs are sorted to the plasma membrane.

N-terminal cleavage of proTGFalpha occurs at the cell surface by a TACE-independent activity.

ProTGFalpha (transforming growth factor alpha precursor) maturation and conversion into soluble TGFalpha is a complex process that involves three proteolytic steps. One, that occurs co-translationally, eliminates the signal sequence. Another, occurring at the juxta-membrane domain, solubilizes TGFalpha.