The Agrobacterium tumefaciens T-DNA gene 6b is an onc gene

In this article it is shown that the T-DNA of Agrobacterium tumefaciens contains besides the well-known cyt and aux genes another gene with an oncogenic effect in plants. The gene in question is called 6^b and causes the formation of small tumors in plant species such as Nicotiana glauca and Kalanchoe tubiflora.     

Expression of the Escherichia coli glutamate dehydrogenase gene in the cyanobacterium Synechococcus PCC6301 causes ammonium tolerance

The unicellular cyanobacterium Synechococcus PCC6301 lacks a hybridisable homologue of the strongly conserved gdhA gene of E. coli that encodes NADP-specific glutamate dehydrogenase. This is consistent with the failure to find this enzyme in extracts of the cyanobacterium. The E. coli gdhA gene was transferred to Synechococcus PCC6301 by transformation with an integrative vector. High levels of glutamate dehydrogenase activity, similar to those found in ammonium grown E. coli cells, were found in these transformants. These transformed cyanobacteria displayed an ammonium tolerant phenotype, consistent with the action of their acquired glutamate dehydrogenase activity as an ammonium detoxification mechanism. Minor differences in colony size and in growth at low light intensity were also observed.     

Nematode Mitochondrial DNA: Anomalies and Applications

The mitochondrial genome of animal cells is currently under intense investigation by molecular, evolutionary, and population biologists. This review summarizes the available information on the molecular biology of nematode mitochondrial DNA and explains how the fundamental knowledge obtained from these basic studies may be applied to nematode systematics, evolution, and diagnostics.     

Secretion and export of IGF-1 in Escherichia coli strain JM101

Summary The processing of LamB-IGF-1 fusion protein and the export of processed IGF-1 (insulin-like growth-factor-1) into the growth medium was examined in the Escherichia coli host strain, JM101. Several strain or plasmid modifications were tried to increase export of periplasmic (Processed) IGF-1 into the growth medium of JM101. These included: (1) use of a lon null mutant strain to increase accumulation levels of unprocessed LamB-IGF-1 fusion protein; (2) use of an alternative drug resistance marker on the expression plasmid rather than beta-lactamase, thereby reducing any competition for processing of LamB-IGF-1 by signal peptidase; (3) examination of whether phage M13 gene III protein expression caused more periplasmic IGF-1 to be exported into the growth medium due to increased outer membrane permeability; and (4) examination of the effect of E. coli or yeast optimized IGF-1 codons. None of these strain or plasmid modifications caused any significant increase in export of IGF-1 into the growth medium of JM101. Solubility studies of LamB-IGF-1 and processed IGF-1 showed that virtually all of the LamB-IGF-1 and IGF-1 remaining within the cell after a 2 h induction period was insoluble. This implied that only soluble LamB-IGF-1 was processed to IGF-1 and that only soluble IGF-1 was exported into the growth medium. Taken together, the results indicated that LamB-IGF-1 and IGF-1 solubility were the limiting factors in secretion of IGF-1 into the periplasm and export of IGF-1 into the growth medium.     

Altered tissue specificity of the revertant shrunken allele upon Dissociation (Ds) excision is associated with loss of expression and molecular rearrangement at the corresponding non-allelic isozyme locus in maize

Summary Transposable element Activator (Ac) induced wild-type stable revertants, derived from McClintock's Dissociation (Ds) insertion shrunken (sh) mutant sh-m5933, have been examined for sucrose synthases, SS1 and SS2, encoded by the revertant (Sh) locus and the non-allelic gene Sus (previously designated as Ss2), respectively. A structurally normal Sh locus has been previously described in these revertants. Immuno-blot (Western) and Southern hybridization analyses reported here identify one of the nine alleles, Sh-r5, as unique for several features. It showed altered tissue specificity, as the SS1 protein encoded by the Sh-r5 allele was readily detectable in the immature embryo which is otherwise characterized by the Sus expression only. The level of Sh-r5 expression at the protein and enzyme level was marked by endosperm specific SS1 abundance and a significant down-regulation in the embryo similar to the standard Sh and Sus loci in endosperm and embryo, respectively. We infer that tissue specific levels of gene expression among maize Ss genes is significantly determined by trans-regulatory factors present in these two tissues. The Sh-r5 strain also exhibited a complete loss of the Sus expression in all tissues tested in the plant. Lack of any detectable phenotypic abnormality in the Sh-r5 strain due to the loss of SS2 protein indicated that either the SS2 protein is nonessential or that the two SS isozymes are functionally compensatory. Genomic filter hybridizations with the Sus cDNA clone indicated that the Sus locus in the Sh-r5 strain was not deleted and was, in fact, unique among these revertants. Together, these data provide an unusual insight into the regulation and function of the two SS isozymes in the maize plant.