The amino terminal domain of HIV-1 Rev is required for discrimination of the RRE from nonspecific RNA.

The ability of HIV-1 Rev to successfully discriminate between specific Rev-responsive elements (RRE) and nonspecific binding sites in the presence of excess nonspecific RNA was examined using filter binding, gel shift, and gel filtration techniques, using purified M4 Rev mutant protein and endoproteinase Lys-C cleaved wild-type Rev. The M4 Rev displayed a slightly reduced binding affinity to the RRE, as well as a tenfold decrease in its ability to discriminate the RRE from non-specific RNA compared to the wild-type Rev. Gel shift and gel filtration chromotography data also showed decreased ability of the mutant to multimerize in the absence or presence of the RRE.

Biochemical characterization of binding of multiple HIV-1 Rev monomeric proteins to the Rev responsive element.

Recombinant HIV-1 Rev protein was overexpressed in Escherichia coli using translational coupling to the beta-glucuronidase gene and demonstrated to interact with high affinity and specificity with the Rev responsive element (RRE). A complex Rev-dependent binding pattern was observed using the gel shift assay which could be simplified to one or two primary bands in the presence of stoichiometric concentrations of RRE. Competition of these bands with a series of homopolymer RNA species demonstrated that Rev is essentially a poly-G binding protein, although poly-I was also shown to compete for specific RRE binding.

Perturbation of the carboxy terminus of HIV-1 Rev affects multimerization on the Rev responsive element.

Perturbations within the transactivation and carboxy-terminal domains of HIV-1 Rev were examined for effects on Rev responsive element (RRE) binding activities in vitro and biological activity in vivo. Binding affinities, specificities, and multimerization of the transactivation mutants M10 and Rev/Rex M10-16 on the RRE were equivalent to wild-type Rev. Substitution of the Rex transactivation domain within Rev resulted in the incorporation of an internal methionine residue which, when cleaved with CNBr and subsequently purified, produced a protein species (CNBr-Rev) unable to fully multimerize on the RRE.

The lentivirus regulatory proteins REV and REX are site specific RNA binding proteins.

These studies demonstrate that HIV-1 REV and HTLV-1 REX are site specific RNA binding proteins. In addition, the REV protein studies indicate a protein domain essential for biological function that is not involved in RRE binding. Lentiviruses are unique among retroviruses in providing gene products to switch expression from early to late genes.

Protocatechuate is not metabolized via catechol in Enterobacter aerogenes.

Protocatechuate is generally metabolized in bacteria by direct oxygenative cleavage to produce beta-carboxymuconate. An exception to this pattern has been suggested by reports that protocatechuate might be metabolized by nonoxidative decarboxylation to catechol in Enterobacter aerogenes. In the present investigation, analysis of mutant strains indicated that this proposed pathway did not make a significant contribution to protocatechuate metabolism in E.

Influence of the catBCE sequence on the phenotypic reversion of a pcaE mutation in Acinetobacter calcoaceticus.

Isofunctional beta-ketoadipate:succinyl coenzyme A transferases I and II are encoded by the pcaE and catE genes, respectively, of Acinetobacter calcoaceticus. The genes are under separate transcriptional control and genetically unlinked. Mutations in the pcaE gene result in a p-hydroxybenzoate-negative (POB-) phenotype, whereas catE mutations cause a benzoate-negative (Ben-) phenotype.

Cloning and genetic organization of the pca gene cluster from Acinetobacter calcoaceticus.

The beta-ketoadipate pathway of Acinetobacter calcoaceticus comprises two parallel metabolic branches. One branch, mediated by six enzymes encoded by the cat genes, converts catechol to succinate and acetyl coenzyme A (acetyl-CoA); the other branch, catalyzed by products of the pca genes, converts protocatechuate to succinate and acetyl-CoA by six metabolic reactions analogous or identical to those of the catechol sequence. We used the expression plasmid pUC18 to construct expression libraries of DNA from an A.

Inducible xylitol dehydrogenases in enteric bacteria.

Morganella morganii ATCC 25829, Providencia stuartii ATCC 25827, Serratia marcescens ATCC 13880, and Erwinia sp. strain 4D2P were found to induce a xylitol dehydrogenase when grown on a xylitol-containing medium. The xylitol dehydrogenases were partially purified from the four strains, and those from M.

Characterization of xylitol-utilizing mutants of Erwinia uredovora.

Of the four pentitols ribitol, xylitol, D-arabitol, and L-arabitol, Erwinia uredovora was able to utilize only D-arabitol as a carbon and energy source. Although attempts to isolate ribitol- or L-arabitol-utilizing mutants were unsuccessful, mutants able to grow on xylitol were isolated at a frequency of 9 X 10(-8). Xylitol-positive mutants constitutively synthesized both a novel NAD-dependent xylitol-4-dehydrogenase, which oxidized xylitol to L-xylulose, and an L-xylulokinase.

Production of D- and L-xylulose by mutants of Klebsiella pneumoniae and Erwinia uredovora.

D-Xylulose and L-xylulose were produced biologically by the oxidation of a corresponding pentitol. A Klebsiella pneumoniae mutant was constructed for the oxidation of D-arabitol to D-xylulose. This mutant constitutively synthesized the D-arabitol permease system and D-arabitol dehydrogenase but was unable to produce the D-xylulokinase of the D-arabitol pathway or the D-xylose isomerase and D-xylulokinase of the D-xylose pathway.

Directed evolution of a second xylitol catabolic pathway in Klebsiella pneumoniae.

Klebsiella pneumoniae PRL-R3 has inducible catabolic pathways for the degradation of ribitol and D-arabitol but cannot utilize xylitol as a growth substrate. A mutation in the rbtB regulatory gene of the ribitol operon permits the constitutive synthesis of the ribitol catabolic enzymes and allows growth on xylitol. The evolved xylitol catabolic pathway consists of an induced D-arabitol permease system that also transports xylitol, a constitutively synthesized ribitol dehydrogenase that oxidizes xylitol at the C-2 position to produce D-xylulose, and an induced D-xylulokinase from either the D-arabitol or D-xylose catabolic pathway.