A new class of histone H2A mutations in Saccharomyces cerevisiae causes specific transcriptional defects in vivo.

Nucleosomes have been shown to repress transcription both in vitro and in vivo. However, the mechanisms by which this repression is overcome are only beginning to be understood. Recent evidence suggests that in the yeast Saccharomyces cerevisiae, many transcriptional activators require the SNF/SWI complex to overcome chromatin-mediated repression. We have identified a new class of mutations in the histone H2A-encoding gene HTA1 that causes transcriptional defects at the SNF/SWI-dependent gene SUC2. Some of the mutations are semidominant, and most of the predicted amino acid changes are in or near the N- and C-terminal regions of histone H2A. A deletion that removes the N-terminal tail of histone H2A also caused a decrease in SUC2 transcription. Strains carrying these histone mutations also exhibited defects in activation by LexA-GAL4, a SNF/SWI-dependent activator. However, these H2A mutants are phenotypically distinct from snf/swi mutants. First, not all SNF/SWI-dependent genes showed transcriptional defects in these histone mutants. Second, a suppressor of snf/swi mutations, spt6, did not suppress these histone mutations. Finally, unlike in snf/swi mutants, chromatin structure at the SUC2 promoter in these H2A mutants was in an active conformation. Thus, these H2A mutations seem to interfere with a transcription activation function downstream or independent of the SNF/SWI activity. Therefore, they may identify an additional step that is required to overcome repression by chromatin.

Differential splicing creates a diversity of transcripts from a neurospecific developmentally regulated gene encoding a protein with new zinc-finger motifs.

We have cloned a novel neurospecific gene, named neuro-d4, by differential screening a rat cerebral cortex cDNA library. Northern blot hybridization showed that neuro-d4 expression is restricted to neuronal tissues both in newborn and adult animals. The level of neuro-d4 mRNA in the rat central nervous system is high during the later stages of embryonic development and gradually decreases during the postnatal period. In situ hybridization suggests that the gene transcripts are localized in neuronal cell bodies. Nucleotide sequences of overlapped cDNA clones and all 12 exons in genomic clone were determined. The deduced protein has consensus sequences for a nuclear localization signal, a Krüppel-type zinc-finger and a new type of cysteine/histidine-rich motif resembling zinc-fingers. Several differential splicing variants were found, each of which influences the structure of the encoded protein.