Functional antagonists of sonic hedgehog reveal the importance of the N terminus for activity.

During development, sonic hedgehog functions as a morphogen in both a short-range contact-dependent and in a long-range diffusable mode. Here, we show using a panel of sonic hedgehog variants that regions near the N terminus of the protein play a critical role in modulating these functions. In the hedgehog responsive cell line C3H10T1/2, we discovered that not only were some N-terminally truncated variants inactive at eliciting a hedgehog-dependent response, but they competed with the wild-type protein for function and therefore served as functional antagonists. These variants were indistinguishable from wild-type sonic hedgehog in their ability to bind the receptor patched-1, but failed to induce the hedgehog-responsive markers, Gli-1 and Ptc-1, and failed to promote hedgehog-dependent differentiation of the cell line. They also failed to support the adhesion of C3H10T1/2 cells to hedgehog-coated plates under conditions where wild-type sonic hedgehog supported binding. Structure-activity data indicated that the N-terminal cysteine plays a key regulatory role in modulating hedgehog activity. The ability to dissect patched-1 binding from signaling events in C3H10T1/2 cells suggests the presence of unidentified factors that contribute to hedgehog responses.

Characterization of a soluble ternary complex formed between human interferon-beta-1a and its receptor chains.

The extracellular portions of the chains that comprise the human type I interferon receptor, IFNAR1 and IFNAR2, have been expressed and purified as recombinant soluble His-tagged proteins, and their interactions with each other and with human interferon-beta-1a (IFN-beta-1a) were studied by gel filtration and by cross-linking. By gel filtration, no stable binary complexes between IFN-beta-1a and IFNAR1, or between IFNAR1 and IFNAR2 were detected. However, a stable binary complex formed between IFN-beta-1a and IFNAR2. Analysis of binary complex formation using various molar excesses of IFN-beta-1a and IFNAR2 indicated that the complex had a 1:1 stoichiometry, and reducing SDS-PAGE of the binary complex treated with the cross-linking reagent dissucinimidyl glutarate (DSG) indicated that the major cross-linked species had an apparent Mr consistent with the sum of its two individual components. Gel filtration of a mixture of IFNAR1 and the IFN-beta-1a/IFNAR2 complex indicated that the three proteins formed a stable ternary complex. Analysis of ternary complex formation using various molar excesses of IFNAR1 and the IFN-beta-1a/IFNAR2 complex indicated that the ternary complex had a 1:1:1 stoichiometry, and reducing SDS-PAGE of the ternary complex treated with DSG indicated that the major cross-linked species had an apparent Mr consistent with the sum of its three individual components. We conclude that the ternary complex forms by the sequential association of IFN-beta-1a with IFNAR2, followed by the association of IFNAR1 with the preformed binary complex. The ability to produce the IFN-beta-1a/IFNAR2 and IFN-beta-1a/IFNAR1/IFNAR2 complexes make them attractive candidates for X-ray crystallography studies aimed at determining the molecular interactions between IFN-beta-1a and its receptor.

Intracellular single-chain antibody inhibits integrin VLA-4 maturation and function.

A single-chain antibody construct was prepared containing the VH and VL regions of anti-(integrin alpha 4) antibody HP1/2, an interchain linker and a KDEL endoplasmic reticulum retention sequence. Intracellular expression of this single-chain antibody caused cell-surface expression of alpha 4 beta 1 integrin to be decreased by 80% on selected RD cells and by 65-100% on selected Jurkat cells, relative to mock transfectants. Immunoprecipitation from single-chain-antibody-transfected cells showed that the single-chain antibody was complexed with the integrin alpha 4 and beta 1 subunits, and the diminished sizes of alpha 4 and beta 1 were consistent with impaired maturation. Furthermore, cell adhesion to alpha 4 beta 1 ligands [VCAM-1 (vascular cell adhesion molecule-1), FN40 (40 kDa chymotryptic fragment of fibronectin) and CS1] was greatly impaired in both RD and Jurkat cells, and cell spreading on immobilized FN40 protein was almost completely eliminated. Thus we conclude that intracellular single-chain antibodies may be used to reduce or eliminate cell-surface expression of a specific integrin, with specific functional consequences. This approach should be generally applicable to other integrin subunits.

Characterization of degP, a gene required for proteolysis in the cell envelope and essential for growth of Escherichia coli at high temperature.

The degP gene, required for proteolysis in the cell envelope of Escherichia coli, maps at approximately 3.5 min on the chromosome. Null mutations in degP result in temperature-sensitive growth. In certain genetic backgrounds, expression of abnormal periplasmic or inner membrane proteins (protein fusions or proteins with internal deletions) enhances the temperature-sensitive phenotype. Such growth defects were used as a selection for cloning the degP gene into Mud4042 and pACYC184 plasmid vectors, and a restriction map was determined. Analysis of deletion and insertion mutations on one of these plasmids showed that the degP gene is approximately 1.5 kilobases in size. The plasmid-encoded DegP protein had an apparent molecular weight of 50,000, as determined by maxicell analysis. Protein fusions between DegP and alkaline phosphatase had high alkaline phosphatase enzymatic activity, indicating that DegP is a periplasmic or membrane protein.

An Escherichia coli mutation preventing degradation of abnormal periplasmic proteins.

A fusion between tsr (encoding the inner membrane protein Tsr) and phoA (encoding the periplasmic protein alkaline phosphatase, AP) generates a membrane-bound hybrid protein (Tsr-AP 2) with AP enzymatic activity. The hybrid protein is proteolytically unstable and is broken down to yield a smaller, soluble species with AP activity. We devised a genetic screen to distinguish between cells containing only membrane-bound AP and those containing soluble AP. The screen depends on diffusion of soluble AP away from cells with a leaky outer membrane to produce a halo of AP activity around colonies on solid growth medium. Several mutants lacking this halo show reduced degradation of Tsr-AP 2. One mutant is also defective in breakdown of five other abnormal periplasmic proteins but not of two cytoplasmic proteins. The mutation in this strain, degP4::Tn5, defines a locus distinct from previously identified loci that affect protein stability or protease activities. This strain may be useful for preventing the breakdown of unstable foreign proteins in Escherichia coli.

Genetic analysis in Salmonella typhimurium with a small collection of randomly spaced insertions of transposon Tn10 delta 16 delta 17.

We report the isolation of a group of 279 Salmonella typhimurium strains carrying randomly spaced insertions of the minitransposon Tn10 delta 16 delta 17 and describe the use of these strains to facilitate genetic analysis. The insertions were isolated initially in individual recombinant lambda clones from a genomic library. Individual insertions were then moved into the S. typhimurium chromosome, where the distribution of insertion sites relative to standard genetic markers was analyzed in a series of transductional crosses. Since a different, randomly chosen clone was used to generate each insertion, the distribution of insertion positions should have been as random as the cloning events leading to the formation of the library. In agreement with this expectation, most S. typhimurium markers tested were cotransducible with one or more of these Tn10 delta 16 delta 17 insertions. We expect that most new mutations will be quickly classified and mapped by determination of the pattern of cotransduction with this set of insertions. This use is illustrated by the analysis of a group of lac operon fusions regulated by anaerobiosis. We also describe several other applications that should make this collection a useful new tool in S. typhimurium genetics.

N-terminal methionine-specific peptidase in Salmonella typhimurium.

Crude extracts of a multiply peptidase-deficient strain of Salmonella typhimurium contain an aminopeptidase that specifically removes N-terminal methionine from peptides. This activity shows pronounced specificity for the peptide's second amino acid. Methionine is removed from peptides with alanine, threonine, or glycine in this position but not when the second amino acid is leucine or methionine. The activity is stimulated by Co2+ and is inhibited by EDTA. Mutations that lead to overproduction (up to 30-fold) of the activity have been obtained by selecting for growth on Met-Gly-Gly as a methionine source. These mutations map at approximately 3 map units, phage P22 cotransducible with leu. The overproducer mutations are dominant to wild type, and duplication of the wild-type allele of the locus leads to a gene dosage effect on peptidase levels. This suggests that the locus of the overproducer mutations may be the structural gene for the peptidase. NaDodSO4/PAGE shows an increased level of a single protein (34 kDa) in the overproducer mutant. This protein is highly enriched in a purified preparation of the peptidase. The specificity of this enzyme suggests that it is involved in the cleavage of methionine from newly synthesized peptide chains. This activity can specifically remove methionine from the N terminus of a completed protein. Treatment of purified, unprocessed (N-terminal methionine) interleukin 1 beta with the purified peptidase results in removal of N-terminal methionine with no additional alterations. N-terminal processing of at least this protein can occur after translation is complete. We propose to call this enzyme peptidase M (methionine-specific aminopeptidase).

Does secA mediate coupling between secretion and translation in Escherichia coli?

An amber mutation in the secA gene of Escherichia coli causes a pleiotropic decrease in the synthesis of secreted proteins, including maltose-binding protein (MBP) and alkaline phosphatase. Reversal of the inhibition of MBP synthesis in secA(Am) strains by signal sequence mutations in the malE gene has been reported. These results suggest a coupling between secretion and translation which involves an interaction between the signal sequence of nascent polypeptides and a cellular secretion machinery. Further analysis reported here indicated that signal sequence mutations of MBP or alkaline phosphatase did not selectively overcome the inhibition of MBP or alkaline phosphatase synthesis in secA(Am) strains. Rather, at a given time in parallel experiments there was substantial variability among closely isogenic secA(Am) strains in the magnitude of the synthesis block; this variability could account for the earlier results. Further experiments suggested that the inhibition of MBP synthesis in secA(Am) strains was caused by depletion of cyclic AMP, leading to decreased transcription of the malE gene. However, the secretion defects in secA(Am) strains were not affected by cyclic AMP levels. Therefore, we conclude that the reduction in MBP synthesis was a secondary consequence of the primary export defect in the secA(Am) strains.

Oxygen regulation in Salmonella typhimurium.

Regulation by oxygen of the peptidase T (pepT) locus of Salmonella typhimurium was studied by measuring beta-galactosidase levels in strains containing a pepT::Mu d1(Apr lac) operon fusion. beta-Galactosidase was induced in anaerobic cultures and late-exponential and stationary-phase aerated cultures. Peptidase T activity also was induced under these growth conditions. pepT+ but not pepT strains will utilize as amino acid sources the tripeptides Leu-Leu-Leu and Leu-Gly-Gly only when grown anaerobically. Mutations at two loci, oxrA and oxrB (oxygen regulation) prevent induction of the pepT locus. The oxrA locus is homologous to the fnr locus of Escherichia coli. We have isolated 12 independent Mu d1 insertions (oxd::Mu d1, oxygen dependent) that show induction of beta-galactosidase in anaerobic cultures and stationary-phase aerated cultures. These insertions fall into nine classes based on map location. All of the oxd::Mu d1 insertions are regulated by oxrA and oxrB and therefore define a global regulon that responds to oxygen limitation.

Overproduction of Salmonella typhimurium peptidase T.

Pseudorevertants able to use L-leucyl-L-leucyl-L-leucine as a leucine source have been isolated from a Salmonella typhimurium strain carrying stable (nonreverting) mutations in pepN, pepA, and pepB. These strains carry mutations at a locus pto (peptidase T overproducer) tightly linked to pepT that cause an elevated expression of the tripeptidase peptidase T. An F' episome carrying the pto and pepT loci has been constructed and used to show that the pto mutations are cis dominant. Expression of beta-galactosidase from a Mu d1(Apr lac) insertion in pepT is increased by pto mutations. The pto mutations, therefore, define a site affecting the transcription of pepT.

Isolation and characterization Salmonella typhimurium mutants lacking a tripeptidase (peptidase T).

Salmonella typhimurium contains an enzyme, peptidase T, that hydrolyzes a variety of tripeptides. Specificity studies with a peptidase activity stain after gel electrophoresis of crude cell extracts showed that peptidase T hydrolyzes tripeptides containing N-terminal methionine, leucine, or phenylalanine. Little or no activity could be detected against dipeptides, N-blocked or C-blocked tripeptides, and tetrapeptides. Analysis of reaction products by high-pressure liquid chromatography showed that peptidase T removes the N-terminal amino acid from tripeptides. Mutants lacking peptidase T were isolated by screening microcultures grown in the wells of plastic microtitration plates for hydrolysis of Met-Ala-Ser or Met-Gly-Gly. Mutations (pepT) that eliminate this enzyme were found to be phage P22 cotransducible with purB at approximately 25 map units on the S. typhimurium map. Comparison of the growth properties of mutant and wild-type strains suggests that peptidase T does not function in utilization of tripeptides to provide amino acids during growth.