The plant pathogen Pectobacterium atrosepticum contains a functional formate hydrogenlyase-2 complex.

Pectobacterium atrosepticum SCRI1043 is a phytopathogenic Gram-negative enterobacterium. Genomic analysis has identified that genes required for both respiration and fermentation are expressed under anaerobic conditions. One set of anaerobically expressed genes is predicted to encode an important but poorly understood membrane-bound enzyme termed formate hydrogenlyase-2 (FHL-2), which has fascinating evolutionary links to the mitochondrial NADH dehydrogenase (Complex I). In this work, molecular genetic and biochemical approaches were taken to establish that FHL-2 is fully functional in P. atrosepticum and is the major source of molecular hydrogen gas generated by this bacterium. The FHL-2 complex was shown to comprise a rare example of an active [NiFe]-hydrogenase-4 (Hyd-4) isoenzyme, itself linked to an unusual selenium-free formate dehydrogenase in the final complex. In addition, further genetic dissection of the genes encoding the predicted membrane arm of FHL-2 established surprisingly that the majority of genes encoding this domain are not required for physiological hydrogen production activity. Overall, this study presents P. atrosepticum as a new model bacterial system for understanding anaerobic formate and hydrogen metabolism in general, and FHL-2 function and structure in particular.

Correlated light and electron microscopy of cell division in large marine oocytes, eggs, and embryos.

The rapid and synchronous divisions of large and transparent oocytes, eggs, and embryos of marine species are exceptionally well suited for microscopic observation. Consequently, these cells have been models for cell division research since its beginnings and contributed some of its first and most fundamental discoveries. While large size and rapid transitions render these cells ideal specimens for light microscopy, the same features constitute a challenge for electron microscopy. Here, we describe example protocols from our work on starfish oocyte meiosis, where we overcome these challenges by using live imaging of fluorescently labeled structures in combination with correlated electron microscopy. In this work, we demonstrate how: (i) to capture a rapid, transient event in time and (ii) to localize a small structure within the large oocyte. These techniques are applicable with minor modifications to oocytes and embryos of other species and, possibly, to other cell types.