Isolation and characterization of proteinase inhibitor I from etiolated tobacco leaves

Proteinase Inhibitor I was induced to accumulate in tobacco (Nicotiana tabaccum) leaves by placing plants in darkness for 10 days at 27 degrees C. The inhibitor was isolated using ammonium sulfate precipitation, Sephadex G-75 chromatography, heating, and affinity chromatography with a chymotrypsin-Sepharose column. Inhibitor I was purified 232-fold with a yield of 34 mg from 2.5 kg of leaves. Affinity-purified tobacco Inhibitor I was shown to be homogeneous by gel electrophoresis in both nondissociating and dissociating buffers. The inhibitor has a molecular weight of 39,000 +/- 1000 determined by gel filtration and, like its potato and tomato counterparts, is composed of five subunits of molecular weight 8100. The tobacco Inhibitor I strongly inhibits chymotrypsin and weakly inhibits trypsin. The chemical, physical, and immunological properties of tobacco Inhibitor I indicate that it is structurally very similar to potato tuber Inhibitor I and tomato leaf Inhibitor I, although the synthesis and accumulation of the three inhibitors in their respective tissues are all under different developmental or environmental regulation.     

Lacunar infarcts in polycythaemia with raised packed cell volumes.

Lacunar (small deep cerebral infarcts) infarction is described in association with raised packed cell volumes. Two patients had polycythaemia vera, one stress polycythaemia. They presented with transient ischaemic episodes and were shown by computed tomography to have lacunes deep in the basal ganglia and internal capsule. Such lesions may be caused by small vessel occlusions related to increased viscosity and impaired oxygen consumption by adjacent tissues. Finding a raised packed cell volume in patients with lacunes and transient ischaemic attacks offers a further possibility of treatment.     

Membrane targeting of RecA during genetic transformation

Recombination in prokaryotes and eukaryotes is mediated by the RecA family of proteins. Although the interactions between RecA and DNA are well studied, the cellular location of these interactions is not known. Using genetic transformation of Streptococcus pneumoniae as a model system, there was increased expression of a protein, colligrin, and RecA, products of the rec locus during genetic transfer. These proteins formed a complex and were found associated with the membranes of genetically competent cells. With immunoelectron microscopy and subcellular fractionation, we showed that the induction of competence led to the translocation of RecA and colligrin to the membrane and to the formation of clusters of RecA in a colligrin-dependent step. Based on the behaviour of colligrin and RecA during genetic exchange and the numerous proteins in prokaryotes and eukaryotes with domains similar to colligrin, we suggest that there may exist a family of proteins, which gathers macromolecules at specific sites in biological membranes.     

Proliferation and relocation of developing lobster neuromuscular synapses

The development of multiterminal innervation from a single identifiable excitatory motoneuron to the lobster distal accessory flexor muscle (DAFM) was studied by serial section electron microscopy. The number, size, and location of neuromuscular synapses and presynaptic dense bars within the peripheral branching pattern of the axon was determined in cross sections of the DAFM in 1st (24-hr-old)-, 4th (2-week-old)-, and 12th (1-year-old)-stage lobsters. The mean size of synapses remains fairly constant in these three stages but synaptic density, i.e., the number of synapses per unit length of fiber, increased more than 20-fold between the 1st and 4th stages and more than 5-fold between the 4th and 12th stages. Synaptic surface area per fiber length showed a parallel increase. Consequently there is a proliferation of synapses along the length of individual muscle fibers during primary development. Furthermore from the 1st stage where only a few fibers are innervated, synapses proliferate to many more fibers in the 4th and to all fibers in the 12th stage. The neuromuscular synapses are distributed in different proportions within the axonal branching pattern in the three stages. Based on the number and size of synapses and presynaptic dense bars, the main axon and primary branches provide almost equal amounts of innervation in the 1st stage. With further branching in the 4th stage, the main axon accounts for only 20–25% of the innervation; the primary branches for 45% and other finer branches the remainder. By the 12th-stage synapses are found only on branches other than the main axon and its primary offshoots. There is therefore a shift in innervation from the main axon to the primary branches and then to the finer branches during primary development. This shift in innervation involves the formation of new synaptic terminals and the restructuring of existing ones into axonal areas. In this way the multiterminal innervation arising from an identifiable motoneuron is remodeled.