Induction and patterning of the cardiac conduction system

The cardiac conduction system (CCS) is the component of the heart that initiates and maintains a rhythmic heartbeat. As the embryonic heart forms, the CCS must continue to develop and mature in a coordinated manner to ensure that proper pace making potential and distribution of action potential is maintained at all stages. This requires not only the formation of distinct and disparate components of the CCS, but the integration of these components into a functioning whole as the heart matures. Though research in this area of development may have lagged behind other areas of heart development, in recent years there has been much progress in understanding the ontogeny of the CCS and the developmental cues that drive its formation. This is largely due to studies on the avian heart as well as the use of molecular biology approaches. This review gives a perspective on advances in understanding the development of the vertebrate CCS, and reports new data illuminating the mechanism of conduction cell determination and maintenance in the mammalian heart. As much of our knowledge about the development of the CCS has been derived from the chick embryo, one important area facing the field is the relationship and similarities between the structure and development of avian and mammalian conduction systems. Specifically, the morphology of the distal elements of the mammalian CCS and the manner in which its components are recruited from working cardiomyocytes are areas of research that will, hopefully, receive more attention in the near future. A more general and outstanding question is how the disparate components of all vertebrate conduction systems integrate into a functional entity during embryogenesis. There is mounting evidence linking the patterning and formation of the CCS to instructive cues derived from the cardiac vasculature and, more specifically, to hemodynamic-responsive factors produced by cardiac endothelia. This highlights the need for a greater understanding of the biophysical forces acting on, and created by, the cardiovascular system during embryonic development. A better understanding of these processes will be necessary if therapeutics are to be developed that allow the regeneration of damaged cardiac tissues or the construction of biologically engineered heart tissues

Delving into the amyloidogenic core of human leukocyte chemotactic factor 2

ALECT2 (leukocyte chemotactic factor 2) amyloidosis is one of the most recently identified amyloid-related diseases, with LECT2 amyloids commonly found in different types of tissues. Under physiological conditions, LECT2 is a 16 kDa multifunctional protein produced by the hepatocytes and secreted into circulation. The pathological mechanisms causing LECT2 transition into the amyloid state are still largely unknown. In the case of ALECT2 patients, there is no disease-causing mutation, yet almost all patients carry a common polymorphism that appears to be necessary but not sufficient to directly trigger amyloidogenesis. In this work, we followed a reductionist methodology in order to detect critical amyloidogenic “hot-spots” during the fibrillation of LECT2. By associating experimental and computational assays, this approach reveals the explicit amyloidogenic core of human LECT2 and pinpoints regions with distinct amyloidogenic properties. The fibrillar architecture of LECT2 polymers, based on our results, provides a wealth of detailed information about the amyloidogenic “hot-spot” interactions and represents a starting point for future peptide-driven intervention in ALECT2 amyloidosis. © 2019 Elsevier Inc

Proliferation of adult sertoli cells in a conditional knockout mouse lacking the gap junctional protein connexin 43

International audienc

Proliferation of adult Sertoli cells following conditional knockout of the gap junctional protein GJA1 (connexin 43) in mice

International audienc