Gene control in eukaryotes and the c-value paradox "excess" DNA as an impediment to transcription of coding sequences.

Ways in which control of gene activity may lead to the observed high DNA content per haploid eukaryote genome are examined. It is proposed that deoxyribonucleoprotein (DNP) acts as a barrier to transcription at two distinct structural levels. At the lower level, melting of the nucleosome supercoil (quaternary structure) and of the nucleosomes (tertiary structure) might be brought about by the process of transcription itself. After unwinding the barrier section, the polymerase would eventually reach the structural gene. The transcripts of noncoding sequences, at least as far as their "unique" sequence components are concerned, may thus have filled their main function through the very process of transcription. The possibility of an inverse relationship between the length of the DNP barrier and the rates of transcription of the coding sequences is to some extent supported by available data. Different modes of coordination between the transcription of mRNA and of hnRNA from a single functional unit of gene action (funga) are considered. An analysis of gene control at high structural levels of DNP is made on the basis of other data, in relation to the concepts of eurygenic and stenogenic control. The concept of a euryon is introduced, namely of a set of linked fugas under common eurygenic control. Structure of order higher than quaternary can be inferred to exist in larger chromomeres of polytene chromosomes and in corresponding sections of ordinary chromosomes. Only moderate amounts of highest order interphase euchromatic structure are likely to be able to be accomodated in average chromomeres and none in very thin chromomeres. Puffs are interpreted as the melting of highest order interphase structure, and the absence of puffs during transcription as the absence of this highest order structure in the resting state of the chromomeres. Genes that are constantly active in all tissues may dispense with highest order interphase structure and with the corresponding control mechanism, and the fugas involved thus may not puff. Puffs, large chromomeres and highest order interphase euchromatic DNP structure seem to be correlated with genes that need to be transcribed only under certain developmental conditions. It is proposed that the function of high order structure is to sequester genetic material, namely mainly controller sequences. Since such high order structure, in most cases, would be built up to house the controller dependencies of just one structural gene, the amount of DNA per structural gene needed for gene control would be considerable, and the concept, if correct, would go a long way towards explaining the c-value paradox ("excess" DNA in eukaryotes). In eurygenic determination, the high order structure is thought to be conditioned for melting or to actually melt to an intermediate level of structure. From there, stenogenic control, leading to transcription, is considered to carry the melting process further to yet lower structural levels...