Morphogenesis of the tail of bacteriophage lambda: III. Morphogenetic pathway

Abstract

Precursors of the tail of bacteriophage λ have been detected by measurements of in vitro complementation activities and serum blocking activity in sucrose gradients of lysates defective in tail genes. On the basis of these measurements, a pathway for the assembly of the λ tail is proposed: The morphogenesis of the λ tail starts from the tail fiber (product of gene J) located at the distal end of the tail, and proceeds to the proximal end. Gene J by itself produces a 15 S structure with serum blocking activity but without any detectable in vitro complementation activity, which may be the least advanced precursor of the λ tail or an abortive product. Functions of genes J, I, K, L are required for the formation of a 15 S precursor that has in vitro complementation activities with J −, I −, K − and L − lysates and serum blocking activity. If the products of genes G and H act on the latter 15 S precursor, a 25 S precursor is made, but this precursor seems either to be in equilibrium with the 15 S precursor or to degrade easily into the 15 S precursor. Gene M has a function of stabilizing the 25 S precursor. After the action of gene M product, the 25 S precursor is ready to serve as a nucleus on which the product of gene V (the major tail protein) assembles. However, gene U product is also necessary at this step for the correct assembly of the major tail protein on the 25 S precursor. Without gene U product the assembly of the major tail protein does not stop at the correct length and a polytail is formed instead of a morphologically normal tail. Finally, gene Z product acts on the morphologically normal tail and makes it a biologically active tail. Without the action of gene Z product, the defective tail binds to a head and forms a phage-like particle which is only very weakly infectious. (The position of gene T in the pathway is not determined, because no sus mutant is available in gene T.) Two abnormal, less efficient pathways are also present in vitro. (1) If gene U product acts on a polytail in an U − lysate, the polytail finally binds to a head and forms a phage particle with an extra long tail which is infectious to a small extent. (2) The function of gene K seems to be bypassed to some extent: K − lysates accumulate particles which sediment as fast as normal phage and which are complemented by other tail − lysates.