NS-4 (nervous system antigen-4), a cell surface antigen of developing and adult mouse brain and sperm.

Morphological changes in the chorion of the Medaka, Oryzias latipes, brought about by the hatching enzyme were examined by transmission as well as scanning electron microscopy. The structure of the intact chorion, especially its thick multilamellar inner layer, does not change during development until about 1 hr before the onset of hatching. As choriolysis proceeds, the inner layer of the chorion is digested to yield soluble proteins of relatively high molecular weight. During this process it appears that each lamella is successively solubilized from the inner surface of the chorion. Finally, a thin outer layer with accompanying villi and attaching filaments remains.Under the experimental conditions used, the enzyme was in direct contact with both the inner and outer layers of the chorion. Because of this, the enzyme could penetrate the outer layer and act on some peripheral parts of the underlying inner layer. Based on these morphological changes, a mechanism is proposed to account for the solubilization of the chorion by the hatching enzyme.     

Structure and invasive behaviour of Plasmodium knowlesi merozoites in vitro.

The structure and invasive behaviour of extracellular erythrocytic merozoites prepared by a cell sieving method have been studied with the electron microscope. Free merozoites contain organelles similar to those described in late schizonts of Plasmodium knowlesi. Their surface is lined by a coat of short filaments. On mixing with fresh red cells, merozoites at first adhere, then cause the red cell surface to invaginate rapidly, often with the formation of narrow membranous channels in the red cell interior. As the merozoite enters the invagination it forms an attachment by its cell coat to the rim of the pit, and finally leaves this coat behind as it is enclosed in a red cell vacuole. Dense, rounded intracellular bodies then move to the merozoite periphery, and apparently rupture to cause further localized invagination of the red cell vacuole. The merozoite finally loses its rhoptries, the pellicle is reduced to a single membrane and the parasite becomes a trophozoite. Invasion is complete by 1 min after adhesion, and the trophozoite is formed by 10 min.     

Xanthine dehydrogenase accumulation in developing Drosophila eyes

Xanthine dehydrogenase activity is assayed by following the oxidation of pterin to isoxanthopterin by spectrofluorometry at the reaction's wavelength peaks: excitation, 344 nm; emission, 412 nm. The method is sensitive to less than 0·1 μU of activity (0·1 pmol/min) and allows the assay of Drosophila imaginal disk homogenates.While the larval eye disk contains less than 0·1 per cent of the individual's XDH, the developing eye becomes a major store, with 30 per cent of the individual's activity by the time of eye pigmentation. The data suggest a basis for the well-known non-autonomous action of the gene rosy, the structural gene for XDH: the enzyme is synthesized in an organ of primary gene expression, and transported through the haemolymph to the eye of the pupa and pharate adult.     

Evolution of sex I. Primitive sex

Sex is a process of fusion of separate hereditary determinants. The advantages which could accrue from such fusions are protection against deleterious mutations and the possibility of combining favorable alleles into a single individual. If the fitness of the aggregate resulting from fusion is greater than its parts there will be strong selective pressure to perpetuate the aggregate in all progeny. Continued fusion presents problems though and new environmental conditions may occur which favor segregation. Segregation is also favored because of the existence of favorable recessive mutations. It is argued that the balance between these alternative goals of phenotype stability versus variety achieved an effective compromise with the development of the meiosis-fusion-mitosis cycle.     

Reversible bacteriophage resistance by shedding the bacterial cell wall

Phages are highly abundant in the environment and pose a major threat for bacteria. Therefore, bacteria have evolved sophisticated defence systems to withstand phage attacks. Here, we describe a previously unknown mechanism by which mono- and diderm bacteria survive infection with diverse lytic phages. Phage exposure leads to a rapid and near-complete conversion of walled cells to a cell-wall-deficient state, which remains viable in osmoprotective conditions and can revert to the walled state. While shedding the cell wall dramatically reduces the number of progeny phages produced by the host, it does not always preclude phage infection. Altogether, these results show that the formation of cell-wall-deficient cells prevents complete eradication of the bacterial population and suggest that cell wall deficiency may potentially limit the efficacy of phage therapy, especially in highly osmotic environments or when used together with antibiotics that target the cell wall.