A Single Amino-Acid Substitution at Lysine 40 of an Arabidopsis thaliana α-tubulin Causes Extensive Cell Proliferation and Expansion Defects

Microtubules are highly dynamic cytoskeletal polymers of α/β‐tubulin heterodimers that undergo multiple post‐translational modifications essential for various cellular functions in eukaryotes. The lysine 40 (K40) is largely conserved in α‐tubulins in many eukaryote species, and the post‐translational modification by acetylation at K40 is critical for neuronal development in vertebrates. However, the biological function of K40 of α‐tubulins in plants remains unexplored. In this study, we show in Arabidopsis thaliana that constitutive expression of mutated forms of α‐tubulin6 (TUA6) at K40 (TUA6^K40A or TUA6^K40Q), in which K40 is replaced by alanine or glutamine, result in severely reduced plant size. Phenotypic characterization of the 35S:TUA6^K40A transgenic plants revealed that both cell proliferation and cell expansion were affected. Cytological and biochemical analyses showed that the accumulation of α‐ and β‐tubulin proteins was significantly reduced in the transgenic plants, and the cortical microtubule arrays were severely disrupted, indicating that K40 of the plant α‐tubulin is critical in maintaining microtubule stability. We also constructed 35S:TUA6^K40R transgenic plants in which K40 of the engineered TUA6 protein is replaced by an arginine, and found that the 35S:TUA6^K40R plants were phenotypically indistinguishable from the wild‐type. Since lysine and arginine are similar in biochemical nature but arginine cannot be acetylated, these results suggest a structural importance for K40 of α‐tubulins in cell division and expansion.     

Direct screening for high-level expression of an introduced α-amylase gene in plants

A method is described for obtaining transgenic plants with a high level of expression of the introduced gene. Tobacco protoplasts were transformed with an expression construct containing a translational fusion between mature -amylase from Bacillus licheniformis and the signal peptide of the tobacco PR-S protein. A total number of 5200 transformed protoplasts was cultured to microcalli and screened for -amylase expression by incubation on media containing starch followed by staining with iodine. The calli were divided into four classes, based on the resulting halo sizes on the plates. The halo sizes were found to correlated with the expression levels in transgenic plants regenerated from the calli. The expression levels varied between 0 and 0.5% of soluble leaf protein in the regenerated transgenic plants. Wider implications of this method are discussed.     

Effect of thedpy-20 androl-6 cotransformation markers on α-tubulin gene expression inC. elegans transformants

An -1 tubulin::lacZ fusion gene was introduced into the germline ofCaenorhabditis elegans, using eitherrol-6 ordpy-20 genomic DNA as a cotransformation marker. Distinct patterns in cellular specificity of the -1 tubulin::lacZ fusion gene expression were observed, depending on the cotransformation marker used. For therol-6 marker, the tubulin fusion gene was expressed in several neurons in the head and tail ganglia and a set of 38–39 ventral cord motor neurons along the body length of the animal during larval and adult development. In contrast, for thedpy-20 marker system, not only were fewer neurons stained in the head and tail region, but also the staining of ventral cord motor neurons was extremely reduced both in number and intensity. Thedpy-20 marked-mediated suppression of the -1 tubulin gene expression was observed both in thecis andtrans configurations. Similar down-regulation in the ventral cord motor neurons was observed when the -2 tubulin::lacZ fusion gene construct was tested in these experiments using thedpy-20 marker. In controls, where the tubulin fusion gene was directly injected to obtain transformants without any marker DNA, the cellular staining pattern was close to the fusion gene expression observed with therol-6 marker DNA. These results underline the importance of the choice of transformation marker system in generation of the transgenic animals, and reveal a down-regulation of the -tubulin fusion gene expression in the ventral cord motor neurons in transgenic animals when thedpy-20 gene was used as a cotransformation marker.     

Cloning and expression of a chicken α-amylase gene

We have isolated and sequenced a genomic clone for a pancreatic α-amylase gene (amy) of the chicken (Gallus gallus). The gene is interrupted by nine introns, spans over 4 kb, and encodes a protein (AMY) of 512 aa that is 83% identical to the human pancreatic α-amylase enzyme. Southern blot analysis of chicken DNA revealed two distinct pancreatic amy loci. In addition, we have generated a cDNA from chicken pancreatic RNA corresponding to the coding sequence of the genomic clone. The cDNA was inserted into a yeast expression vector, and the resulting construct used to transform Saccharomyces cerevisiae cells. Transformed yeast cells synthesized and secreted active AMY enzyme, and the gel migration pattern of the α-amylase produced by the yeast cells was identical to that of the native chicken enzyme.     

Mismatch recognition function of Arabidopsis thaliana MutSγ

Genetic stability depends in part on an efficient DNA lesion recognition and correction by the DNA mismatch repair (MMR) system. In eukaryotes, MMR is initiated by the binding of heterodimeric MutS homologue (MSH) complexes, MSH2–MSH6 and MSH2–MSH3, which recognize and bind mismatches and unpaired nucleotides. Plants encode another mismatch recognition protein, named MSH7. MSH7 forms a heterodimer with MSH2 and the protein complex is designated MutSγ. We here report the effect the expression of Arabidopsis MSH2 and MSH7 alone or in combination exert on the genomic stability of Saccharomyces cerevisiae. AtMSH2 and AtMutSγ proteins failed to complement the hypermutator phenotype of an msh2 deficient strain. However, overexpressing AtMutSγ in MMR proficient strains generated a 4-fold increase in CAN1 forward mutation rate, when compared to wild-type strains. Can^r mutation spectrum analysis of AtMutSγ overproducing strains revealed a substantial increase in the frequency of base substitution mutations, including an increased accumulation of base pair changes from G:C to A:T and T:A to C:G, G:C or A:T. Taken together, these results suggest that AtMutSγ affects yeast genomic stability by recognizing specific mismatches and preventing correction by yeast MutSα and MutSβ, with subsequent inability to interact with yeast downstream proteins needed to complete MMR.     

Isolation and characterization of a gene encoding α-tubulin from Candida albicans

A gene encoding the α-tubulin of Candida albicans has been cloned and characterized. Nucleotide sequence analysis reveals the presence of an intron within the structural gene and predicts the synthesis of a polypeptide of 448 amino acid residues. Comparison of nucleotide and amino acid sequences with the Saccharomyces cerevisiae α-tubulin encoding genes shows a 75% homology and about 92% similarity respectively. In contrast to S. cerevisiae, C. albicans appears to possess only one gene for α-tubulin which is able to functionally complement a S. cerevisiae cold-sensitive tub1 mutant.     

Tissue specific expression of an α-skeletal actin-lacZ fusion gene during development in transgenic mice

Transgenic mice carrying a chimaeric transgene containing 730 bp of the 5-flanking sequences and the entire first intron of the rat -skeletal actin gene fused to thelacZ reporter gene have been produced by microinjection. ThelacZ reporter gene was used to verify the suitability of using the rat -actin promoter elements to target expression of genes of agricultural and therapeutic value exclusively to skeletal and heart muscle cells and fibres of transgenic mice. Expression of the transgene indicates a tightly regulated developmental and muscle specific control of the rat -skeletal actin gene, making it a useful promoter for gene targeting to muscle tissues. The cells destined to form muscle tissues in these transgenic mice are readily visualized in intact embryos by staining for -galactosidase activity, making them a suitable animal model for studying the origin and development of skeletal and cardiac muscle tissues.