We have examined codon bias in 207 plant gene sequences collected from Genbank and the literature. When this sample was further divided into 53 monocot and 154 dicot genes, the pattern of relative use of synonymous codons was shown to differ between these taxonomic groups, primarily in the use of G + C in the degenerate third base. Maize and soybean codon bias were examined separately and followed the monocot and dicot codon usage patterns respectively. Codon preference in ribulose 1,5 bisphosphate and chlorophyll a/b binding protein, two of the most abundant proteins in leaves was investigated. These highly expressed are more restricted in their codon usage than plant genes in general.
We have examined expression of several insecticidal crystal protein (ICP) genes of Bacillus thuringiensis in transgenic tobacco plants and electroporated carrot protoplasts. We determined that low levels of lepidopteran toxin cryIA(b) ICP gene expression in plants and electroporated carrot cells is due to RNA instability. We used a series of 3' deleted by cryIA(b) constructs directed by the cauliflower mosaic virus 35S promoter to demonstrate that this instability is minimally contained in the first 579 bases of the gene in both systems. This instability may result from 5'----3' as well as 3'----5' RNA metabolism. The coleopteran toxic cryIIIA gene was also examined in electroporated carrot cells, and found to be poorly expressed. A model for improvement of ICP RNA stability in plants is presented.
Rhesus macaques represent important animal models for biomedical research. The ability to identify macaque major histocompatibility complex (Mhc) alleles is crucial for fully understanding these models of autoimmune and infectious disease. Here we describe a rapid and unambiguous way to distinguish DRB alleles in the rhesus macaque using the polymerase chain reaction, denaturing gradient gel electrophoresis (DGGE), and direct sequencing. The highly variable second exon of Mamu-DRB alleles was amplified using generic DRB primers and alleles were separated by DGGE. DNA was then reamplified from plugs removed from the gel and alleles were determined using fluorescent-based sequencing. Validity of this typing procedure was confirmed by identification of all DRB alleles for three macaques previously characterized by cloning and sequencing techniques. Importantly, our analysis revealed DRB alleles not previously identified in the three reference animals. Using this technique, we identified 40 alleles in fifteen unrelated macaques. On the basis of phylogenetic tree analyses, 14 new DRB alleles were assigned to 10 different Mhc-DRB lineages. Interestingly, two of the new DRB6 lineages had previously been identified in prosimians and pigtailed macaques. Whereas traditional DRB typing methods provide limited information, our new technique provides a simple and relatively rapid way of identifying DRB alleles for tissue typing, determining individual identification and studies of disease association and susceptibility. This new technique should also contribute to ongoing studies of Mhc function and evolution in many different species of nonhuman primates.
High-resolution HLA-DRB typing is required for bone marrow transplantation between unrelated donors and recipients and also for identification of novel HLA-DRB alleles. Here we describe a method for the unambiguous identification of HLA-DRB alleles using the polymerase chain reaction (PCR), denaturing gradient gel electrophoresis (DGGE) and direct sequencing. The highly variable second exon of all HLA-DRB1, -DRB3, -DRB4, -DRB5, -DRB6 and -DRB7 alleles was amplified using a single pair of generic DRB-specific primers and alleles were separated by DGGE. DNA was then reamplified from plugs removed from the gel and the sequences of these alleles were determined using fluorescent-based sequencing and allele-assignment software. The validity of this typing procedure was confirmed by identification of HLA-DRB alleles for 17 individuals previously characterized by PCR-SSP and/or cloning and sequencing techniques. We identified 34 different HLA-DRB alleles in these 17 unrelated individuals. Importantly, our analysis revealed HLA-DRB1 alleles which had not been identified using the PCR-SSP typing technique. Additionally, alleles from the HLA-DRB3, -DRB4 and -DRB5 loci were identified. Whereas traditional HLA-DRB typing methods provide limited information or require the use of multiple oligonucleotide primers or probes, our technique provides a reliable, specific and relatively rapid way of identifying all HLA-DRB alleles for high-resolution tissue typing.
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