The AMA1 sequence was isolated from a genomic library of Aspergillus nidulans on the basis of its ability to enhance transformation frequency and generate phenotypically unstable transformants in this fungus. These properties were previously shown to be the result of extrachromosomal replication of AMA1-bearing plasmids. Here we demonstrate that AMA1 is an inverted duplication of a sequence which has other isolated genomic copies. These sequences (mobile Aspergillus transformation enhancers, or MATEs) share a high degree of sequence similarity and exhibit some features characteristic of mobile elements, including a potential Met-tRNA priming site, similar to that found in retrotransposons of the Ty-copia group. The nucleotide sequence does not encode any extended polypeptides but contains ARS-consensus matches and a multiply repeated 'Spe' motif, which may be described as a symmetrically duplicated topoisomerase I recognition site. This motif was shown to be a target for illegitimate recombination events. The mobility of members of the MATE family is inferred from the observation that their chromosomal locations are highly variable between wild Aspergillus isolates. The inverted duplication AMA1 is present in laboratory strains derived from the Glasgow isolate but not in other wild isolates tested. This indicates that the inverted duplication AMA1 is of recent evolutionary origin and probably does not exert any conserved function in the chromosome. We discuss possible connections between structural features of AMA1 and its ability to promote extrachromosomal plasmid replication.
We describe a new method of gene cloning by complementation of mutant alleles which obviates the need for construction of a gene library in a plasmid vector in vitro and its amplification in Escherichia coli. The method involves simultaneous transformation of mutant strains of the fungus Aspergillus nidulans with (i) fragmented chromosomal DNA from a donor species and (ii) DNA of a plasmid without a selectable marker gene, but with a fungal origin of DNA replication ('helper plasmid'). Transformant colonies appear as the result of the joining of chromosomal DNA fragments carrying the wild-type copies of the mutant allele with the helper plasmid. Joining may occur either by ligation (if the helper plasmid is in linear form) or recombination (if it is cccDNA). This event occurs with high efficiency in vivo, and generates an autonomously replicating plasmid cointegrate. Transformants containing Penicillium chrysogenum genomic DNA complementing A. nidulans niaD, nirA and argB mutations have been obtained. While some of these cointegrates were evidently rearranged or consisted only of unaltered replicating plasmid, in other cases plasmids could be recovered into E. coli and were subsequently shown to contain the selected gene. The utility of this "instant gene bank" technique is demonstrated here by the molecular cloning of the P. canescens trpC gene.
The AMA1 sequence is an efficient plasmid replicator and transformation enhancer in Aspergillus nidulans. It comprises two long perfect inverted repeats (MATE elements) flanking a short, unique, central spacer. Subclone analysis indicates that the complete inverted duplication, but not the unique central spacer, is necessary for efficient plasmid replication. The smallest fragments able to affect transformation efficiency lie within the AT-rich portions of the inverted repeats. We demonstrate that two or more copies of the repeat in any relative orientation are able to perform the replicator function. A single copy of a MATE element increases transformation frequency to a modest extent but leads to multiple rearrangement, unstable integration or concatenation of vector molecules. Multimeric concatenates generated during this process are more sable mitotically, and when reisolated, transform the fungus at a much higher frequency than the original monomeric vector. Selection for multiple products which resemble amplified DNA in various eukaryotic systems.
Antisense expression of a portion of the gene encoding the major carbon catabolite repressor CREA in Aspergillus nidulans resulted in a substantial increase in the levels of glucose-repressible enzymes, both endogenous and heterologous, in the presence of glucose. The derepression effect was approximately one-half of that achieved in a null creA mutant. Unlike results for that mutant, however, growth parameters and colony morphology in the antisense transformants were not affected.
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