Selective antagonism to the cadherin BT-R1 interferes with calcium-induced adhesion of epithelial membrane vesicles.

BT-R(1) is a member of the cadherin superfamily of proteins and is expressed in the midgut epithelium of Manduca sexta during larval development. Previously, we showed that calcium ions influence the structure and stability of BT-R(1) on brush border membrane vesicles (BBMVs) prepared from M. sexta midgut epithelium. In the present study, the effects of calcium and Cry1Ab toxin, produced by Bacillus thuringiensis, on the adhesive properties of BBMVs were investigated. Addition of calcium to a suspension of BBMVs promoted adhesion and aggregation of the vesicles. Treatment of BBMVs with trypsin or lowering the pH (pH 4.0) of the BBMV suspension abolished calcium-induced vesicle aggregation, whereas treatment with deglycosylating enzymes did not affect the aggregation of vesicles, indicating that adhesion and clustering of BBMVs involves protein-protein interactions. Preincubation of BBMVs with Cry1Ab toxin, which specifically binds to BT-R(1) with high affinity and disrupts the midgut epithelium of M. sexta, caused a 50% decrease in calcium-induced vesicle aggregation. The inhibitory effects of the Cry1Ab toxin on BBMV aggregation was blocked completely when the toxin was preincubated with a peptide containing the toxin-binding site of BT-R(1). Cry3A toxin, which is similar in molecular structure to Cry1Ab but does not bind to BT-R(1) and is not toxic to M. sexta larvae, did not affect BBMV aggregation. The results of this study demonstrate that the adhesive function of BT-R(1) is compromised by the Cry1Ab toxin, which acts as a selective antagonist, and supports the notion that BT-R(1) is critical in preserving the integrity of larval midgut epithelium in M. sexta.

The germ cell-specific transcription factor ALF. Structural properties and stabilization of the TATA-binding protein (TBP)-DNA complex.

The assembly and stability of the RNA polymerase II transcription preinitiation complex on a eukaryotic core promoter involves the effects of TFIIA on the interaction between TATA-binding protein (TBP) and DNA. To extend our understanding of these interactions, we characterized properties of ALF, a germ cell-specific TFIIA-like factor. ALF was able to stabilize the binding of TBP to DNA, but it could not stabilize TBP mutants A184E, N189E, E191R, and R205E nor could it facilitate binding of the TBP-like factor TRF2/TLF to a consensus TATA element. However, phosphorylation of ALF with casein kinase II resulted in the partial restoration of complex formation using mutant TBPs. Studies of ALF-TBP complexes formed on the Adenovirus Major Late (AdML) promoter revealed protection of the TATA box and upstream sequences from -38 to -20 (top strand) and -40 to -22 (bottom strand). The half-life and apparent K(D) of this complex was determined to be 650 min and 4.8 +/- 2.7 nm, respectively. The presence of ALF or TFIIA did not significantly alter the ability of TBP to bind TATA elements from several testis-specific genes. Finally, analysis of the distinct, nonhomologous internal regions of ALF and TFIIAalpha/beta using circular dichroism spectroscopy provided the first evidence to suggest that these domains are unordered, a result consistent with other genetic and biochemical properties. Overall, the results show that while the sequence and regulation of the ALF gene are distinct from its somatic cell counterpart TFIIAalpha/beta, the TFIIAgamma-dependent interactions of these factors with TBP are nearly indistinguishable in vitro. Thus, a role for ALF in the assembly and stabilization of initiation complexes in germ cells is likely to be similar or identical to the role of TFIIA in somatic cells.