Generating Targeted Gene Knockout Lines in Physcomitrella patens to Study Evolution of Stress-Responsive Mechanisms.

The moss Physcomitrella patens possesses highly efficient homologous recombination allowing targeted gene manipulations and displays many features of the early land plants including high tolerance to abiotic stresses. It is therefore an invaluable model organism for studies of gene functions and comparative studies of evolution of stress responses in plants. Here, we describe a method for generating targeted gene knockout lines in P. patens using a polyethylene glycol-mediated transformation of protoplasts including basic in vitro growth, propagation, and maintenance techniques.

Regulation of plant gene expression by alternative splicing.

AS (alternative splicing) is a post-transcriptional process which regulates gene expression through increasing protein complexity and modulating mRNA transcript levels. Regulation of AS depends on interactions between trans-acting protein factors and cis-acting signals in the pre-mRNA (precursor mRNA) transcripts, termed 'combinatorial' control. Dynamic changes in AS patterns reflect changes in abundance, composition and activity of splicing factors in different cell types and in response to cellular or environmental cues. Whereas the SR protein family of splicing factors is well-studied in plants, relatively little is known about other factors influencing the regulation of AS or the consequences of AS on mRNA levels and protein function. To address fundamental questions on AS in plants, we are exploiting a high-resolution RT (reverse transcription)-PCR system to analyse multiple AS events simultaneously. In the present paper, we describe the current applications and development of the AS RT-PCR panel in investigating the roles of splicing factors, cap-binding proteins and nonsense-mediated decay proteins on AS, and examining the extent of AS in genes involved in the same developmental pathway or process.

Alternative splicing in plants.

The impact of AS (alternative splicing) is well-recognized in animal systems as a key regulator of gene expression and proteome complexity. In plants, AS is of growing importance as more genes are found to undergo AS, but relatively little is known about the factors regulating AS or the consequences of AS on mRNA levels and protein function. We have established an accurate and reproducible RT (reverse transcription)-PCR system to analyse AS in multiple genes. Initial studies have identified new AS events confirming that current values for the frequency of AS in plants are likely to be underestimates.

Monitoring changes in alternative precursor messenger RNA splicing in multiple gene transcripts.

Alternative splicing (AS) increases the proteomic and functional capacity of genomes through the generation of alternative mRNA transcripts from the same gene. AS is now estimated to occur in a third of Arabidopsis and rice genes, and includes genes involved in the control of growth and development, responses to stress and signalling. Regulation of AS reflects the interactions between positive and negative cis sequences in the precursor messenger RNA and a range of trans-acting factors. The levels and activities of these factors differ in different cells and growth conditions. To identify changes in AS in multiple genes simultaneously, we have established a reproducible RT-PCR panel that can analyse 96 alternative splicing events and accurately measure the ratio of alternatively spliced products. This procedure detected statistically significant changes in AS in different plant organs, in plants grown under different light and day-length conditions, and in plants overexpressing splicing factors. The system provides a convenient, medium-throughput means of monitoring changes in AS in multiple genes. It can readily be applied to much larger or targeted sets of gene transcripts to generate information on the significance and regulation of AS in plant growth and development, specific processes and responses to external stimuli.