Inhibition of the Psychrotrophic Bacteria of Raw Milk by Addition of Lactic Acid Bacteria

Two commercial cultures of lactic acid bacteria (LAB) were added to raw milk in order to inhibit the development of psychrotrophic bacteria. The effects of inoculation level, pH development, media for culture preparation, and milk heat treatment on the inhibitory activity of LAB were studied. Inoculation levels of 2.5 × 10⁶/mL and less of LAB did not significantly reduce psychrotrophic growth. Maximum inoculation level of LAB studied was 25 × 10⁶/mL and this reduced psychrotrophic development by a factor of 10; however, milk pH was reduced to 6.54 over 48 h of incubation at 7°C with this inoculation level. This acidification was not responsible for the inhibitory activity of LAB on psychrotrophs. The LAB were more effective when psychrotroph populations had high multiplication rates. Initial populations of Pseudomonas putida in pasteurized milk did not influence the activity of the LAB. Pseudomonas putida grew faster in sterile milk than in pasteurized milk, but average inhibition rates of LAB were similar in both media.

Mutations that affect phosphorylation of the adenovirus DNA-binding protein alter its ability to enhance its own synthesis

The multifunctional adenovirus single-strand DNA-binding protein (DBP) is highly phosphorylated. Its phosphorylation sites are located in the amino-terminal domain of the protein, and its DNA- and RNA-binding activity resides in the carboxy-terminal half of the polypeptide. We have substituted cysteine or alanine for up to 10 of these potential phosphorylation sites by using oligonucleotide-directed mutagenesis. Alteration of one or a few of these sites had little effect on the viability of virus containing the mutated DBP. However, when eight or more sites were altered, viral growth decreased significantly. This suggests that the overall phosphorylation state of the protein was more important than whether any particular site was modified. The reduction in growth correlated with both depressed DNA replication and expression of late genes. This reduction was probably the result of lower DBP accumulation in mutant-infected cells. Interestingly, although the stability of the mutated DBP was not affected, DBP synthesis and the level of its mRNA were depressed 5- to 10-fold for the underphosphorylated protein. These results suggest that DBP enhances its own expression and imply that phosphorylation of the DBP may be important for this function. Similarities to several eucaryotic transcriptional activators, which are composed of negatively charged activating domains and separate binding domains, are discussed.

Nuclear localization of the adenovirus DNA-binding protein: requirement for two signals and complementation during viral infection

The adenovirus DNA-binding protein (DBP) is an abundant multifunctional protein located primarily in the nuclei of infected cells. To define sequences involved in nuclear transport of DBP, a series of point and small deletion mutants were constructed via oligonucleotide-directed mutagenesis. Two short stretches of basic amino acids located in the amino-terminal domain (amino acids 42 to 46 and 84 to 89) were identified. Their importance, however, depended on the context in which DBP was expressed. Disruption of either site prevented nuclear localization after transient expression in transfected 293 cells, implying that two nuclear localization signals are necessary for transport of this nuclear protein. In contrast, the mutant DBPs synthesized during viral infection were located either primarily in the nucleus or in the nucleus and cytoplasm, depending on the mutation and the stage of the viral infection. Thus, the nuclear localization defect could be complemented by viral infection, perhaps through the interaction of the mutant polypeptide with a virus-encoded or -induced factor(s).

cis-acting elements and a trans-acting factor affecting alternative splicing of adenovirus L1 transcripts

Expression of the L1 region of adenovirus is temporally regulated by alternative splicing to yield two major RNAs encoding the 52- to 55-kilodalton (52-55K) and IIIa polypeptides. The distal acceptor site (IIIa) is utilized only during the late phase of infection, whereas the proximal site (52-55K) is used at both early and late times. Several parameters that might affect this alternative splicing were tested by using expression vectors carrying the L1 region or mutated versions of it. In the absence of a virus-encoded or -induced factor(s), only the 52-55K acceptor was used. Decreasing the distance between the donor and the IIIa acceptor had no effect. Removal of the 52-55K acceptor induced IIIa splicing slightly, implying competition between the two acceptors. Fusion of the IIIa exon to the 52-55K intron greatly enhanced splicing of the IIIa junction, suggesting that the IIIa exon does not contain sequences that inhibit splicing. Thus, the lack of splicing to the IIIa acceptor in the absence of a virus-encoded or -induced factor(s) is probably due to the absence of a favorable sequence and/or the presence of a negative element 5' of the IIIa splice junction, or both. The presence of several adenovirus gene products, including VA RNAs, the E2A DNA-binding protein, and the products of E1A and E1B genes, did not facilitate use of the IIIa acceptor. In contrast, the simian virus 40 early proteins, probably large T antigen, induced IIIa splicing. This result, together with those of earlier studies, suggest that T antigen plays a role in modulation of alternative RNA splicing.

Isolation and characterization of a viable adenovirus mutant defective in nuclear transport of the DNA-binding protein

The isolation and characterization of an adenovirus mutant, Ad5dl802r1, containing two independent deletions in the 72-kilodalton (kDa) DNA-binding protein (DBP) gene is described. The two deletions remove amino acids 23 through 105 of DBP, resulting in the production of a 50-kDa product. Expression of this truncated DBP was delayed 12 to 24 h compared with that of the 72-kDa protein produced by wild-type adenovirus type 5. The DBP was located primarily in the cytoplasm of infected cells, whereas the wild-type product was predominantly nuclear. Therefore, DBP appears to contain a nuclear localization signal within the deleted region. Ad5dl802r1 DNA synthesis, viral late gene expression, and virus production were all delayed 12 to 24 h and were approximately 10-fold lower than with wild-type adenovirus type 5. These phenotypic properties can be accounted for by the delay in synthesis and the inefficient accumulation of the 50-kDa DBP within the nucleus of infected cells. The truncated DBP also lacks the majority of amino acids which are phosphorylated in the normal protein. The loss of these phosphorylation sites does not appear to seriously impair the ability of the protein to carry out its functions.

Hexon trimerization occurring in an assembly-defective, 100K temperature-sensitive mutant of adenovirus 2

Analysis of 100K-defective temperature-sensitive adenovirus mutants confirmed the multifunctional character of the nonstructural, virus-coded 100K protein. In addition to its function in hexon trimerization (altered in H5ts1), and its possible direct or indirect role in hexon transport to nucleus (mutated in H2ts118), genetic and biochemical evidence was presented that 100K play some critical role in the scaffolding process of adenovirus capsid. This function appeared to be defective in H2ts107 and to map between coordinates 69.0 and 69.9, leftward from the H5ts1 lesion (70-73 map units; Arrand, 1978). This corresponded to the central domain of the 100K protein, between amino acid 300 and 400 from the N end. DNA sequencing of cloned fragments of H2ts107 DNA overlapping the mutation revealed two point mutations on the same codon at nucleotide 25,082 and 25,083 (GAC----GCA), corresponding to a nonconservative amino acid change (aspartic acid----alanine) at position 324 in the 100K sequence. 100K of adenovirus 2 wild type (WT) was found to bind in significant amounts to novobiocin-affinity column, and to be coeluted with hexon, penton, IIIa, and cellular topoisomerase II activity, by novobiocin- or ATP-Mg2+-containing buffers. H2ts107 100K also bound to novobiocin column, but the elution pattern differed from that of WT, suggesting some alteration in the affinity of the mutated 100K for novobiocin. The same behavior on affinity column as H2ts107 100K was observed for 90K, a cleavage product of the 100K, found in great abundance in H2ts107 at 39.5 degrees and corresponding to the C-terminal moiety of the 100K molecule. This implied that the "novobiocin-binding" domain of the 100K was not confined at its N terminus, and was altered in the H2ts107 mutant.

Possible role of ADP-ribosylation of adenovirus core proteins in virus infection

We have investigated the role of poly(ADP)-ribosylation of adenoviral proteins in virus infection. Viral core proteins V and the precursor to protein VII were shown to be in vivo and in vitro acceptors of ADP-ribose. In vivo ADP-ribosylation was restricted to viral proteins as the histones were not labeled during the late phase of infection. The ADP-ribosylated core proteins were assembled into mature virus particles. In vitro ADP-ribosylation of adenoviral core proteins performed with purified poly(ADP-ribose) polymerase led to relaxation of the chromatin structure of both ts1 and wild type pyridine cores and pentonless particles and triggered the complete dissociation of wild type particles. A critical role for poly(ADP)-ribosylation in virus infection was confirmed by measuring the effect of the inhibitors 3-aminobenzamide and nicotinamide on virus particle yield and infectivity. Both inhibitors depressed particle yield by up to 9-fold, but infectivity was reduced by up to 10(4)-fold. These results suggest that ADP-ribosylation of adenovirus core proteins may have a role in virus decapsidation.

Isolation and characterization of the Streptomyces cattleya temperate phage TG1

A temperate actinophage, TG1, was isolated from soil by growth on Streptomyces cattleya and has been shown to be potentially useful for the cloning of DNA in this organism and other streptomycetes. It forms stable lysogens by integration at a unique site on the chromosome. The phage genome consists of 41 kb of double-stranded DNA with cohesive ends. It has unique sites for ClaI, NdeI, PstI, SmaI, and XbaI. The PstI site has been shown to be in a dispensable region of the phage genome. Deletions (2 kb in length) were obtained which retain this site and should be useful for the cloning of DNA.

Morphogenesis of human adenovirus type 2: sequence of entry of proteins into previral and viral particles

The initial steps of adenovirus capsid morphogenesis and the sequence of entry of structural and nonstructural proteins into assembly-intermediate (IM) particles were investigated by pulse-chase labeling, temperature shifts, and cycloheximide inhibition of particle formation. The experiments were performed on wild-type and two assembly-defective, temperature-sensitive mutants, H2 ts 112 and H2 ts 107. The sequence of events in the adenovirus assembly can be schematized as follows. (i) Hexons, pentons, and protein IX assembled with scaffolding proteins 100K, PVIII, and PVII, precursor to the major core protein, to form a previral particle banding at a density of 1.285 in CsCl; (ii) additional incorporation of maturation and/or stabilization proteins IIIa, 50K, 39K, 28K, and PVI led to 1.295 IM; (iii) exit of 100K, 39K, and 28K, and entry of viral DNA gave rise to 1.370 IM; (iv) dephosphorylation and/or exit of 50K and exchange with core protein V and processing of precursors to VII, VI, VIII, and DNA-terminal protein resulted in formation of infectious 1.345 virion. The polypeptide composition of the new class of assembly-intermediate particles elicited by H2 ts 107 (1.285 IM), suggested that 100K, PVIII, and also PVII might serve as scaffold components for adenovirus capsid building.