Transcriptional Regulation of xyn2 in Hypocrea jecorina

ABSTRACT The xylanase system of the filamentous fungus Hypocrea jecorina (Trichoderma reesei) consists of two specific xylanases, Xyn1 and Xyn2, which are simultaneously expressed during growth on xylan but respond differentially to low-molecular-weight inducers. Using in vivo footprinting analysis of xylan-induced and noninduced mycelia, we detected two adjacent nucleotide sequences (5′-AGAA-3′ on the noncoding strand and 5′-GGGTAAATTGG-3′, referred to as the xylanase-activating element [XAE], on the coding strand, respectively) to bind proteins. Among these, binding to the AGAA-box is only observed under noninduced conditions, whereas binding to XAE is constitutive. Electrophoretic mobility shift assay with heterologously expressed components of the H. jecorina Hap2/3/5 protein complex and the cellulase regulator Ace2 suggests that these two transactivators form the protein complex binding to XAE. H. jecorina transformants, containing correspondingly mutated versions of the xyn2 promoter fused to the Aspergillus niger goxA gene as a reporter, revealed that the elimination of protein binding to the AGAA-box resulted in a threefold increase in both basal and induced transcription, whereas elimination of Ace2 binding to its target in XAE completely eliminated transcription under both conditions. Destruction of the CCAAT-box by insertion of a point mutation prevents binding of the Hap2/3/5 complex in vitro and results in a slight increase in both basal and induced transcription. These data support a model of xyn2 regulation based on the interplay of Hap2/3/5, Ace2 and the AGAA-box binding repressor.

Origin of Gene Overlap: The Case of TCP1 and ACAT2

The human acetyl-CoA acetyltransferase 2 gene, ACAT2, codes for a thiolase, an enzyme involved in lipid metabolism. The human T-complex protein 1 gene, TCP1, encodes a molecular chaperone of the chaperonin family. The two genes overlap by their 3′-untranslated regions, their coding sequences being located on opposite DNA strands in a tail-to-tail orientation. To find out how the overlap might have arisen in evolution, the homologous genes of the zebrafish, the African toad, caiman, platypus, opossum, and wallaby were identified. In each species, standard or long polymerase chain reactions were used to determine whether the ACAT2 and TCP1 homologs are closely linked and, if so, whether they overlap. The results reveal that the overlap apparently arose during the transition from therapsid reptiles to mammals and has been retained for >200 million years. Part of the overlapping untranslated region shows remarkable sequence conservation. The overlap presumably arose during the chromosomal rearrangement that brought the two unrelated and previously separated genes together. One or both of the transposed genes found by chance signals that are necessary for the processing of their transcripts to be present on the noncoding strand of the partner gene.

Homogenization of 5S ribosomal genes on the noncoding strand of the rDNA units of two crustacean species

We amplified and cloned twelve 28S-18S ribosomal RNA gene intergenic regions from two crustacean species, the copepod Calanus finmarchicus and the euphausid Thysanoessa raschi. Hybridization of single-stranded and double-stranded versions of these clones with single-stranded oligonucleotide probes showed that at least one 5S ribosomal gene is present on the noncoding strand of all twelve 28S-18S intergenic regions from each species.Key words: concerted evolution, 5S ribosomal genes, 18S ribosomal genes, 28S ribosomal genes.

Specific binding of proteins to the noncoding strand of a crucial element of the variant surface glycoprotein, procyclin, and ribosomal promoters of trypanosoma brucei.

The variant surface glycoprotein (VSG) and procyclin promoters of Trypanosoma brucei recruit an RNA polymerase sharing characteristic with polymerase I, but there is no sequence homology between them nor between these promoters and ribosomal promoters. We report the detailed characterization of the VSG promoter. The 70-bp region upstream of the transcription start site was sufficient for full promoter activity. Mutational analysis revealed three short critical stretches at positions -61 to -59 (box 1), -38 to -35 (box 2), and -1 to +1 (start site), the spacing of which was essential. These elements were conserved in the promoter for a metacyclic VSG gene. Hybrid sequences containing box 1 of the VSG promoter and box 2 of the ribosomal promoter were active. A specific binding of proteins to the noncoding strand of box 2, but not to double-stranded DNA, occurred. Competition experiments indicated that these proteins also bind to the corresponding region of the metacyclic VSG, procyclin, and ribosomal promoters. Binding of such a protein, of 40 kDa, appeared to be shared by these promoters.

An antisense oligonucleotide complementary to a sequence in I gamma 2b increases gamma 2b germline transcripts, stimulates B cell DNA synthesis, and inhibits immunoglobulin secretion.

An antisense phosphorothioate (S)-oligonucleotide to a sequence in the intervening (I) region of the gamma 2b immunoglobulin (Ig) heavy chain gene inhibits Ig secretion by B cells stimulated with lipopolysaccharide (LPS) or LPS plus interleukin 4. It is also a striking stimulant of DNA synthesis by resting B cells. The antisense S-oligonucleotide causes a 10-20-fold increase in the expression of the gamma 2b germline transcript. Among mutants of the antisense S-oligonucleotide, some show all the effects whereas others are inactive. A similar hierarchy exists in the quantitative biological activities of mutant S-oligonucleotides and in their capacity to hybridize to the sense oligonucleotide, strongly suggesting that an I gamma 2b sequence in the RNA transcript or in the noncoding strand of the DNA is the target of the antisense S-oligonucleotide. The possible relationship of the overexpression of the germline gamma 2b transcript to the biological functions of the I gamma 2b antisense S-oligonucleotide is discussed.

Independent regulation of transcription of the two strands of the c-myc gene

Previously we demonstrated the existence of transcripts from the noncoding strand of a rearranged, truncated c-myc gene in murine plasmacytomas in which this oncogene is translocated to an immunoglobulin constant-region gene element (M. Dean, R. B. Kent, and G. E. Sonenshein, Nature [London] 305:443-446, 1983). Here we report on the transcription of the two strands of a normal, unrearranged c-myc gene. We examined the effects of gene rearrangements, growth state transitions, and differentiation on the relative levels of usage of the two strands. Transcription from intron 1 to exon 3 of the murine c-myc gene was studied in in vitro nuclear runoff assays. The level of transcription of the noncoding strand across this region of a germ line c-myc gene in a murine B-cell lymphoma line was comparable to the level observed in plasmacytomas with translocated c-myc genes. Rapid changes in transcription of the coding strand of the c-myc gene could be seen during growth arrest of WEHI 231 cells and during activation of splenic T lymphocytes. Transcription of the noncoding strand was constitutive during these growth state transitions and during activation of primary cultures of quiescent calf aortic smooth muscle cells as well. In contrast, differentiation of murine erythroleukemia cells was accompanied by an early drop in transcription of the two strands of this gene. The ramifications of these findings with respect to measurements of c-myc gene transcription and to the regulation of this gene are discussed.

Independent regulation of transcription of the two strands of the c-myc gene.

Previously we demonstrated the existence of transcripts from the noncoding strand of a rearranged, truncated c-myc gene in murine plasmacytomas in which this oncogene is translocated to an immunoglobulin constant-region gene element (M. Dean, R. B. Kent, and G. E. Sonenshein, Nature [London] 305:443-446, 1983). Here we report on the transcription of the two strands of a normal, unrearranged c-myc gene. We examined the effects of gene rearrangements, growth state transitions, and differentiation on the relative levels of usage of the two strands. Transcription from intron 1 to exon 3 of the murine c-myc gene was studied in in vitro nuclear runoff assays. The level of transcription of the noncoding strand across this region of a germ line c-myc gene in a murine B-cell lymphoma line was comparable to the level observed in plasmacytomas with translocated c-myc genes. Rapid changes in transcription of the coding strand of the c-myc gene could be seen during growth arrest of WEHI 231 cells and during activation of splenic T lymphocytes. Transcription of the noncoding strand was constitutive during these growth state transitions and during activation of primary cultures of quiescent calf aortic smooth muscle cells as well. In contrast, differentiation of murine erythroleukemia cells was accompanied by an early drop in transcription of the two strands of this gene. The ramifications of these findings with respect to measurements of c-myc gene transcription and to the regulation of this gene are discussed.