Identification of a novel sequence that governs both polyadenylation and alternative splicing in region E3 of adenovirus.

Region E3 encodes four major overlapping mRNAs with different splicing patterns. There are two poly(A) sites, an upstream site called E3A and a downstream site called E3B. We have analyzed virus mutants with deletions or insertions in E3 in order to identify sequences that function in the alternative processing of E3 pre-mRNAs, and to understand what determines which poly(A) sites and which splice sites are used. In previous studies we established that the 5' boundary of the E3A poly(A) signal is at an ATTAAA sequence. We now show, using viable virus mutants, that the 3' boundary of the E3A signal is located within 47-62 nucleotides (nt) downstream of the ATTAAA (17-32 nt downstream of the last microheterogenous poly(A) addition site). Our data further suggest that the spacing between the ATTAAA, the cleavage sites, and the essential downstream sequences may be important in E3A 3' end formation. Of particular interest, these mutants suggest a novel mechanism for the control of alternative pre-mRNA processing. Mutants which are almost completely defective in E3A 3' end formation display greatly increased use of a 3' splice site located 4 nt upstream of the ATTAAA. The mRNA that uses this 3' splice site is polyadenylated at the E3B poly(A) site. We suggest, for this particular case, that alternative pre-mRNA processing could be determined by a competition between trans-acting factors that function in E3A 3' end formation or in splicing. These factors could compete for overlapping sequences in pre-mRNA.     

Involvement of cytoplasmic membranes in the non-lytic infection of K-562 cells by Semliki Forest virus

An analysis of the human leukemia cell line, K-562, infected with Semliki Forest virus, has been made with transmission electron microscopy. In contrast to the usual surface budding of the enveloped virus on the plasma membrane of vertebrate cells leading to cytolysis within 20 h, K-562 cells do not show surface budding, and the cells remain intact for periods of several months. Several unusual features of the infection include: 1) the rough endoplasmic reticulum arranges early into continuous perinuclear chains; 2) during the time of virus replication and release, the nucleocapsids aggregate on the cytoplasmic side of internal vesicles in the region of the cell where the Golgi complex is normally located; and 3) during this same time period, the vesicles are seen to contain enveloped virions and rod-like formations, a result suggesting that budding has occurred into these vesicles. Viruses are presumably released from the cell as these vesicles fuse with the plasma membrane. By 12 days post-infection and thereafter, the intact cells show electron-dense aggregates of chromatin, large vacuoles and lipid inclusions throughout the cytoplasm, and only a few virion-containing vesicles.     

Modification of the microtubule-binding and ATPase activities of kinesin by N-ethylmaleimide (NEM) suggests a role for sulfhydryls in fast axonal transport

N-Ethylmaleimide, an agent which alkylates free sulfhydryls in proteins, has been used to probe the role of sulfhydryls in kinesin, a motor protein for the movement of membrane-bounded organelles in fast axonal transport. When squid axoplasm is perfused with concentrations of NEM higher than 0.5 mM, organelle movements in both the anterograde and retrograde directions cease, and the vesicles remain attached to microtubules. Incubation of highly purified bovine brain kinesin with similar concentrations of NEM modifies the enzyme's microtubule-stimulated ATPase activity and promotes the binding of kinesin to microtubules in the presence of ATP. These results suggest that alkylation of sulfhydryls on kinesin alters the conformation of the protein in a manner that profoundly affects its interactions with ATP and microtubules. The NEM-sensitive sulfhydryls, therefore, may provide a valuable tool for the dissection of functional domains of the kinesin molecule and for understanding the mechanochemical cycle of this enzyme.     

A note on the isolation and propagation of lytic phages from Streptococcus uberis and their potential for strain typing

Thirty-eight of 98 strains of Streptococcus uberis were shown to be carrying lysogenic phage. Although propagating strains were rare, host modification by field strains sensitive to phage was used to increase the lytic spectra. When 120 nationally-collected strains were challenged with 25 phages, selected on the basis of differing lytic spectra and propagating strains, 30% were susceptible to at least one phage, increasing to 42% when 480 strains from a single farm were considered. A typing system based on susceptibility to lytic phage was considered feasible.     

Molecular motors in axonal transport

Neurons require a large amount of intracellular transport. Cytoplasmic polypeptides and membrane-bounded organelles move from the perikaryon, down the length of the axon, and to the synaptic terminals. This movement occurs at distinct rates and is termed axonal transport. Axonal transport is divided into the slow transport of cytoplasmic proteins including glycolytic enzymes and cytoskeletal structures and the fast transport of membrane-bounded organelles along linear arrays of microtubules. The polypeptide compositions of the rate classes of axonal transport have been well characterized, but the underlying molecular mechanisms of this movement are less clear. Progress has been particularly slow toward understanding force-generation in slow transport, but recent developments have provided insight into the molecular motors involved in fast axonal transport. Recent advances in the cellular and molecular biology of one fast axonal transport motor, kinesin, have provided a clearer understanding of organelle movement along microtubules. The availability of cellular and molecular probes for kinesin and other putative axonal transport motors have led to a reevaluation of our understanding of intracellular motility.