Behavioural and functional characterization of Kv10.1 (Eag1) knockout mice.

Kv10.1 (Eag1), member of the Kv10 family of voltage-gated potassium channels, is preferentially expressed in adult brain. The aim of the present study was to unravel the functional role of Kv10.1 in the brain by generating knockout mice, where the voltage sensor and pore region of Kv10.1 were removed to render non-functional proteins through deletion of exon 7 of the KCNH1 gene using the '3 Lox P strategy'. Kv10.1-deficient mice show no obvious alterations during embryogenesis and develop normally to adulthood; cortex, hippocampus and cerebellum appear anatomically normal. Other tests, including general health screen, sensorimotor functioning and gating, anxiety, social behaviour, learning and memory did not show any functional aberrations in Kv10.1 null mice. Kv10.1 null mice display mild hyperactivity and longer-lasting haloperidol-induced catalepsy, but there was no difference between genotypes in amphetamine sensitization and withdrawal, reactivity to apomorphine and haloperidol in the prepulse inhibition tests or to antidepressants in the haloperidol-induced catalepsy. Furthermore, electrical properties of Kv10.1 in cerebellar Purkinje cells did not show any difference between genotypes. Bearing in mind that Kv10.1 is overexpressed in over 70% of all human tumours and that its inhibition leads to a reduced tumour cell proliferation, the fact that deletion of Kv10.1 does not show a marked phenotype is a prerequisite for utilizing Kv10.1 blocking and/or reduction techniques, such as siRNA, to treat cancer.

Characterization and plant expression of a glyphosate-tolerant enolpyruvylshikimate phosphate synthase.

BACKGROUND: Glyphosate tolerance is a dominant trait in modern biotech crops. RESULTS: A gene encoding a glyphosate-tolerant EPSP synthase (aroA(1398)) from bacterial strain ATX1398 was cloned and characterized. The protein is initiated at a GTG translational start codon to produce a protein that provides robust glyphosate resistance in Escherichia coli (Mig) Cast & Chalm. The aroA(1398) protein was expressed and purified from E. coli, and key kinetic values were determined (K(i) = 161 microM; K(m)(PEP) = 11.3 microM; k(cat) = 28.3 s(-1)). The full-length enzyme is 800-fold more resistant to glyphosate than the maize EPSP synthase while retaining high affinity for the substrate phosphoenol pyruvate. To evaluate further the potential of aroA(1398), transgenic maize events expressing the aroA(1398) protein were generated. T(0) plants were screened for tolerance to glyphosate sprays at 1.3x commercial spray rates, and T(1) plants were selected that completely resisted glyphosate sprays at 1x, 2x and 4x recommended spray rates in field trials. CONCLUSION: These data suggest that aroA(1398) is a suitable candidate for conferring glyphosate tolerance in transgenic crop plants.

Reduction of protease inhibitor activity by expression of a mutant Bowman-Birk gene in soybean seed.

A mutant Bowman-Birk gene was created that encoded an inactive high-sulfur product. It was used to transform soybean line Asgrow 3237. Transformants bearing the mutant gene were identified by GUS expression, PCR analysis, and Southern analysis. The amount of steady state mRNA from the mutant gene in the transformed plants showed that the gene was highly expressed, but the amount of message from the unmodified Bowman-Birk gene did not change detectably. Proteins synthesized at the direction of the mutant Bowman-Birk gene accumulated in seeds of the transformed plants, and there was a marked decrease in the ability of extracts prepared from these seeds to inhibit trypsin and chymotrypsin despite the presence of Kunitz trypsin inhibitor. The more prevalent mRNA from the mutant gene was considered to out-compete message from the native genes to decrease the amount of active Bowman-Birk inhibitor.

Two subtilisin-like proteases from soybean.

Two subtilisin-like proteases (SLP) were identified in soybean (Glycine max [L.] Merr.). The first, SLP-1, was localized in seed coats early in seed development, but became undetectable with anti-SLP-1 antibodies as seed fill progressed. A partial purification of SLP-1 was achieved using a two step chromatographic procedure. NH2-terminal sequence analysis of the partially purified enzyme permitted primers to be designed that were used to amplify cDNA encoding SLP-1. A genomic clone encoding SLP-1 was also obtained. Characterization of the cDNA and partially purified SLP-1 revealed the initial translation product was an 82 694 MW precursor. After removal of a signal peptide, the mature protein was formed by removal of an NH2-terminal propeptide. A COOH-terminal peptide also appeared to be removed from some of the protease molecules. DNA blot analysis suggested that at least one additional SLP gene was present in soybean. The second gene, SLP-2, was subsequently cloned and characterized. Although the coding regions for SLP-1 and SLP-2 were homologous, their promoters were quite divergent. RT-PCR revealed that SLP-2 message was found in the mature plant and in cotyledons of germinating seeds. Although SLP-2 mRNA could be identified in developing seeds, the message was at least an order of magnitude less abundant than that for SLP-1, and it was mis-spliced such that a chain termination event would preclude obtaining a product. As with SLPs from other organisms, the functions of the soybean proteases are unknown. However, SLP-1 is one of only a few proteins from soybean seed coats that have been described.