SPT6, an essential gene that affects transcription in Saccharomyces cerevisiae, encodes a nuclear protein with an extremely acidic amino terminus

Spt6 Association with RNA Polymerase II Directs mRNA Turnover During Transcription

Spt6 is an essential histone chaperone that mediates nucleosome reassembly during gene transcription. Spt6 also associates with RNA polymerase II (RNAPII) via a tandem Src2 homology domain. However, the significance of Spt6-RNAPII interaction is not well understood. Here, we show that Spt6 recruitment to genes and the nucleosome reassembly functions of Spt6 can still occur in the absence of its association with RNAPII. Surprisingly, we found that Spt6-RNAPII association is required for efficient recruitment of the Ccr4-Not de-adenylation complex to transcribed genes for essential degradation of a range of mRNAs, including mRNAs required for cell-cycle progression. These findings reveal an unexpected control mechanism for mRNA turnover during transcription facilitated by a histone chaperone.

Genetic ablation of interacting with Spt6 (Iws1) causes early embryonic lethality

IWS1 is an RNA-polymerase II (RNAPII)-associated transcription elongation factor whose biological functions are poorly characterized. To shed some light on the function of this protein at the organismal level, we performed a systematic tissue analysis of its expression and generated Iws1-deficient mice. A thorough immunohistochemical characterization shows that IWS1 protein is present in the nucleus of all cells in most of the examined tissues, with few notable exceptions. We also report that ablation of Iws1 consistently causes lethality at the pre-implantation stage with high expression of the gene in fertilized oocytes. In summary, we are providing evidence that Iws1 is expressed in all adult organs and it is an essential gene for mouse embryonic development.

Shaping the cellular landscape with Set2/SETD2 methylation

Chromatin structure is a major barrier to gene transcription that must be disrupted and re-set during each round of transcription. Central to this process is the Set2/SETD2 methyltransferase that mediates co-transcriptional methylation to histone H3 at lysine 36 (H3K36me). Studies reveal that H3K36me not only prevents inappropriate transcriptional initiation from arising within gene bodies, but that it has other conserved functions that include the repair of damaged DNA and regulation of pre-mRNA splicing. Consistent with the importance of Set2/SETD2 in chromatin biology, mutations of SETD2, or mutations at or near H3K36 in H3.3, have recently been found to underlie cancer development. This review will summarize the latest insights into the functions of Set2/SETD2 in genome regulation and cancer development.

A feed forward circuit comprising Spt6, Ctk1 and PAF regulates Pol II CTD phosphorylation and transcription elongation

The C-terminal domain (CTD) of RNA polymerase II is sequentially modified for recruitment of numerous accessory factors during transcription. One such factor is Spt6, which couples transcription elongation with histone chaperone activity and the regulation of H3 lysine 36 methylation. Here, we show that CTD association of Spt6 is required for Ser2 CTD phosphorylation and for the protein stability of Ctk1 (the major Ser2 CTD kinase). We also find that Spt6 associates with Ctk1, and, unexpectedly, Ctk1 and Ser2 CTD phosphorylation are required for the stability of Spt6-thus revealing a Spt6-Ctk1 feed-forward loop that robustly maintains Ser2 phosphorylation during transcription. In addition, we find that the BUR kinase and the polymerase associated factor transcription complex function upstream of the Spt6-Ctk1 loop, most likely by recruiting Spt6 to the CTD at the onset of transcription. Consistent with requirement of Spt6 in histone gene expression and nucleosome deposition, mutation or deletion of members of the Spt6-Ctk1 loop leads to global loss of histone H3 and sensitivity to hydroxyurea. In sum, these results elucidate a new control mechanism for the regulation of RNAPII CTD phosphorylation during transcription elongation that is likely to be highly conserved.

Deletion of Candida albicans SPT6 is not lethal but results in defective hyphal growth

As a means to study surface proteins involved in the yeast to hypha transition, human monoclonal antibody fragments (single-chain variable fragments, scFv) have been generated that bind to antigens expressed on the surface of Candida albicans yeast and/or hyphae. A cDNA expression library was constructed from hyphae, and screened for immunoreactivity with scFv5 as a means to identify its cognate antigen. A reactive clone contained the 3' end of the C. albicans gene, orf 19.7136, designated SPT6 based on homology to Saccharomyces cerevisiae, where its product functions as a transcription elongation factor. A mutant containing a homozygous deletion of SPT6 was isolated, demonstrating that unlike S. cerevisiae, deletion of this gene in C. albicans is not lethal. Growth of this strain was severely impaired, however, as was its capacity to undergo filamentous growth. Reactivity with scFv5 was not detected in the mutant strain, although its impaired growth complicates the interpretation of this finding. To assess C. albicansSPT6 function, expression of the C. albicans gene was induced in a defined S. cerevisiaespt6 mutant. Partial complementation was seen, confirming that the C. albicans and S. cerevisiae genes are functionally related in these species.

Structure and in vivo requirement of the yeast Spt6 SH2 domain

During transcription elongation through chromatin, the Ser2-phosphorylated C-terminal repeat domain of RNA polymerase II binds the C-terminal Src homology 2 (SH2) domain of the nucleosome re-assembly factor Spt6. This SH2 domain is unusual in its specificity to bind phosphoserine, rather than phosphotyrosine and because it is the only SH2 domain in the yeast genome. Here, we report the high-resolution crystal structure of the SH2 domain from Candida glabrata Spt6. The structure combines features from both structural subfamilies of SH2 domains, suggesting it resembles a common ancestor of all SH2 domains. Two conserved surface pockets deviate from those of canonical SH2 domains, and may explain the unusual phosphoserine specificity. Differential gene expression analysis reveals that the SH2 domain is required for normal expression of a subset of yeast genes, and is consistent with multiple functions of Spt6 in chromatin transcription.

Yeast spt6-140 mutation, affecting chromatin and transcription, preferentially increases recombination in which Rad51p-mediated strand exchange is dispensable

We have shown that the spt6-140 and spt4-3 mutations, affecting chromatin structure and transcription, stimulate recombination between inverted repeats by a RAD52-dependent mechanism that is very efficient in the absence of RAD51, RAD54, RAD55, and RAD57. Such a mechanism of recombination is RAD1-RAD59-dependent and yields gene conversions highly associated with the inversion of the repeat. The spt6-140 mutation alters transcription and chromatin in our inverted repeats, as determined by Northern and micrococcal nuclease sensitivity analyses, respectively. Hyper-recombination levels are diminished in the absence of transcription. We believe that the chromatin alteration, together with transcription impairment caused by spt6-140, increases the incidence of spontaneous recombination regardless of whether or not it is mediated by Rad51p-dependent strand exchange. Our results suggest that spt6, as well as spt4, primarily stimulates a mechanism of break-induced replication. We discuss the possibility that the chromatin alteration caused by spt6-140 facilitates a Rad52p-mediated one-ended strand invasion event, possibly inefficient in wild-type chromatin. Our results are consistent with the idea that the major mechanism leading to inversions might not be crossing over but break-induced replication followed by single-strand annealing.

The yeast protein complex containing cdc68 and pob3 mediates core-promoter repression through the cdc68 N-terminal domain

Transcription of nuclear genes usually involves trans-activators, whereas repression is exerted by chromatin. For several genes the transcription mediated by trans-activators and the repression mediated by chromatin depend on the CP complex, a recently described abundant yeast nuclear complex of the Pob3 and Cdc68/Spt16 proteins. We report that the N-terminal third of the Saccharomyces cerevisiae Cdc68 protein is dispensable for gene activation but necessary for the maintenance of chromatin repression. The absence of this 300-residue N-terminal domain also decreases the need for the Swi/Snf chromatin-remodeling complex in transcription and confers an Spt- effect characteristic of chromatin alterations. The repression domain, and indeed the entire Cdc68 protein, is highly conserved, as shown by the sequence of the Cdc68 functional homolog from the yeast Kluyveromyces lactis and by database searches. The repression-defective (truncated) form of Cdc68 is stable but less active at high temperatures, whereas the known point-mutant form of Cdc68, encoded by three independent mutant alleles, alters the N-terminal repression domain and destabilizes the mutant protein.

Role of the human homolog of the yeast transcription factor SPT5 in HIV-1 Tat-activation

The transactivator protein Tat stimulates transcriptional elongation from the HIV-1 LTR. One mechanism by which Tat increases HIV-1 transcription is by interacting with RNA polymerase II and TFIIH to increase phosphorylation of the polymerase C-terminal domain. Recent studies indicate that specific elongation factors may also be required to modulate Tat function. Here, we used biochemical analysis and in vitro transcription assays to identify cellular factors required for Tat activation. This analysis resulted in the purification of a cellular factor Tat-CT1 which is a human homolog of the yeast transcription factor SPT5. Immunodepletion of Tat-CTl from HeLa extract demonstrated that this factor was involved in transcriptional activation by Tat. However, the absence of this factor from HeLa extract did not prevent transcriptional activation by VP16. These findings are consistent with a model in which Tat-mediated effects on transcriptional elongation are mediated in part by the action of the human homolog of the yeast transcription factor SPT5.

Mutations in the SPT4, SPT5, and SPT6 genes alter transcription of a subset of histone genes in Saccharomyces cerevisiae

The SPT4, SPT5, and SPT6 gene products define a class of transcriptional repressors in Saccharomyces cerevisiae that are thought to function through their effects on chromatin assembly or stability. Mutations in these genes confer a similar range of phenotypes to mutations in HIR genes, which encode transcriptional repressors that regulate expression of many of the core histone genes. Here we show that mutations in the three SPT genes also affect transcription of the histone genes that reside at the HTA1-HTB1 locus. HTA1-lacZ transcription was reduced in each spt mutant background, an effect that required a negative site in the HTA1 promoter. The transcriptional effect could be reversed by the overproduction of histones H2A and H2B in an spt4 mutant and histones H3 and H4 in all three spt mutants. Suppression of the spt4 transcriptional defect was dependent on the overproduction of both histones H2A and H2B, and required the presence of N-terminal amino acids in both histones. The results are consistent with the idea that the effects of the spt mutations on nucleosome assembly and/or stability activate repressors of HTA1 transcription.

The yeast CCR4 protein is neither regulated by nor associated with the SPT6 and SPT10 proteins and forms a functionally distinct complex from that of the SNF/SWI transcription factors

The CCR4 protein is specifically required for the increased transcription at the ADH2 locus resulting from mutations in the SPT10 (CRE1) and SPT6 (CRE2) genes and is also required for the expression of ADH2 and other genes under non-fermentative growth conditions. The mechanism by which mutations in CCR4 suppress defects in SPT10 and SPT6 was examined. The SPT10 and SPT6 genes were shown not to control CCR4 mRNA or protein expression nor did SPT10 and SPT6 proteins co-immuneprecipitate with CCR4. CCR4 association with two other proteins, 195 and 185 kDa in size, was unaffected by either spt10 or spt6 mutations. Also, the ability of CCR4 to activate transcription when fused to the LexA DNA binding domain was not specifically enhanced by defects in either SPT10 or SPT6. These results suggest that SPT10 and SPT6, in negatively regulating transcription at ADH2, act through a factor that requires CCR4 function, but do not regulate CCR4 expression, control its activity, physically interact with it, or affect its binding to other factors. The relationship of CCR4 to the group of general transcription factors, SNF2, SNF5, SNF6 and SWI1 and SWI3, which comprise a multisubunit complex required for ADH2 and other genes' expression, was also examined. CCR4 protein expression was not controlled by these factors nor did they co-immuneprecipitate or associate with CCR4. In addition, a ccr4 mutation had little effect on an ADH2 promoter alteration in contrast to the large effects displayed by mutations in SNF2 and SNF5. These data suggest that CCR4 acts by a separate mechanism from that used by the SNF/SWI general transcription factors in affecting gene expression.

Histone acetylation: facts and questions

The DNA of eukaryotic cells is organized in a complex with proteins, either as interphase chromatin or mitotic chromosomes. Nucleosomes, the structural subunits of chromatin, have long been considered as static structures, incompatible with processes occurring in chromatin. During the past few years it has become evident that the histone part of the nucleosome has important regulatory functions. Some of these functions are mediated by the N-terminal core histone domains which contain sites for posttranslational modifications, among them lysine residues for reversible acetylation. Recent results indicate that acetylation and deacetylation of N-terminal lysines of nucleosomal core histones represent a means of molecular communication between chromatin and the cellular signal transduction network, resulting in heritable epigenetic information. Data on enzymes involved in acetylation and the pattern of acetylated lysine sites on chromosomes, as well as genetic data on yeast transcriptional repression, suggest that acetylation may lead to structural transitions as well as specific signalling within distinct chromatin domains.

Pleiotropic function of ArgRIIIp (Arg82p), one of the regulators of arginine metabolism in Saccharomyces cerevisiae. Role in expression of cell-type-specific genes

ArgRIIIp (Arg82p), together with ArgRIp (Arg80p), ArgRIIp (Arg81p) and Mcm1p, regulates the expression of arginine anabolic and catabolic genes. An argRIII mutant constitutively expresses five anabolic enzymes and is impaired in the induction of the synthesis of two catabolic enzymes. A genomic disruption of the ARGRIII gene not only leads to an argR phenotype, but also prevents cell growth at 37 degrees C. The disrupted strain is sterile especially in an alpha background and transcription of alpha- and a-specific genes (MF alpha 1 and STE2) is strongly reduced. By gel retardation assays we show that the binding of the Mcm1p present in a crude protein extract from an argRIII mutant strain to the P(PAL) sequence is impaired. Sporulation of alpha/a argRIII::URA3 homozygous diploids is also affected. Overexpression of Mcm1p in an argRIII-disrupted strain restores the mating competence of the strain, the ability to form a protein complex with P(PAL) DNA in vitro, and the regulation of arginine metabolism. However, overexpression of Mcm1p does not complement the sporulation deficiency of the argRIII-disrupted strain, nor does it complement its growth defect at 37 degrees C. Western blot analysis indicates that Mcm1p is less abundant in a strain devoid of ArgRIIIp than in wild type.

Reporter genes in transgenic mice

Although in vivo models utilizing endogenous reporter genes have been exploited for many years, the use of reporter transgenes to dissect biological issues in transgenic animals has been a relatively recent development. These transgenes are often, but not always, of prokaryotic origin and encode products not normally associated with eukaryotic cells and tissues. Some encode enzymes whose activities are detected in cell and tissue homogenates, whereas others encode products that can be detected in situ at the single cell level. Reporter genes have been used to identify regulatory elements that are important for tissue-specific gene expression or for development; they have been used to produce in vivo models of cancer; they have been employed for the study of in vivo mutagenesis; and they have been used as a tool in lineage analysis and for marking cells in transplantation experiments. The most commonly used in situ reporter gene is lacZ, which encodes a bacterial beta-galactosidase, a sensitive histochemical marker. Although it has been used with striking success in cultured cells and in transgenic mouse embryos, its postnatal in vivo expression has been unreliable and disappointing. Nevertheless, the ability to express reporter genes in transgenic mice has been an invaluable resource, providing insights into in vivo biological mechanisms. The development of new in vivo models, such as those in which expression of transgenes can be activated or repressed, should produce transgenic animal systems that extend our capacity to address heretofore unresolved biological questions.

Molecular characterization of the SPT23 gene: a dosage-dependent suppressor of Ty-induced promoter mutations from Saccharomyces cerevisiae

SPT genes are suppressors of mutations induced by the retrotransposon Ty in Saccharomyces cerevisiae. All SPT genes isolated to date suppress Ty-induced mutations by altering transcription. SPT23 was identified as a multicopy suppressor of the Ty-induced promoter mutations his4-912 delta and lys2-61. Multicopy expression of SPT23 suppresses a variety of Ty-induced promoter mutations, including the MAT-regulated alleles his4-917(480) and lys2-173R2. Here, we report the initial characterization of the SPT23 gene, including its nucleotide sequence and location in the yeast genome. The SPT23 gene contains a 1854 base pair open reading frame. Searches of the current data bases show no homology between SPT23 and previously described genes or proteins. The SPT23 gene is located between RAM2 and MAK11 on the left arm of chromosome XI. Tn10-LUK insertional mutagenesis of the SPT23 gene indicates that SPT23 is not essential for vegetative growth and spt23 mutations do not confer an Spt- phenotype.

A novel strategy for the immunological tagging of cDNA constructs

We describe the construction of pBact-myc, an expression vector that incorporates an immunological 'tag' into the produced polypeptide. When transfected into recipient cell lines, tagged protein fragments derived from any source can be visualised using a single monoclonal antibody (mAb). The neuronal-associated protein 2c (MAP2c) was tagged with a sequence encoding a peptide from the human c-myc gene. The preservation of normal function of the tagged protein was shown by transfecting it into cultured cell lines. No difference in binding ability to cellular microtubules could be observed between the myc-tagged MAP2c and the wild-type forms, and both produced the same characteristic changes in microtubule organisation. This approach is being used to study the biological function of selected fragments of MAP2c and other MAP-encoding genes. The pBact-myc expression vector represents a fast and convenient way to produce tagged polypeptides of selected sequences encoding whole proteins or fragments, for the analysis of their function in living cells.

Molecular and genetic analysis of the SNF7 gene in Saccharomyces cerevisiae

Mutations in the SNF7 gene of Saccharomyces cerevisiae prevent full derepression of the SUC2 (invertase) gene in response to glucose limitation. We report the molecular cloning of the SNF7 gene by complementation. Sequence analysis predicts that the gene product is a 27-kDa acidic protein. Disruption of the chromosomal locus causes a fewfold decrease in invertase derepression, a growth defect on raffinose, temperature-sensitive growth on glucose, and a sporulation defect in homozygous diploids. Genetic analysis of the interactions of the snf7 null mutation with ssn6 and spt6/ssn20 suppressor mutations distinguished SNF7 from the SNF2, SNF5 and SNF6 genes. The snf7 mutation also behaved differently from mutations in SNF1 and SNF4 in that snf7 ssn6 double mutants displayed a synthetic phenotype of severe temperature sensitivity for growth. We also mapped SNF7 to the right arm of chromosome XII near the centromere.

TSF1 to TSF6, required for silencing the Saccharomyces cerevisiae GAL genes, are global regulatory genes

The Saccharomyces cerevisiae GAL1 and GAL10 genes are controlled in response to the availability of galactose and glucose by multiple activating and repressing proteins bound at adjacent or overlapping sites in UASG. Negative control elements in UASG, designated GAL operators GALO1 to GALO6, are required to silence basal level transcription of GAL1 and GAL10 when galactose is absent. We isolated and characterized recessive mutations in six nuclear genes, TSF1 to TSF6, that impair silencing of GAL1 and GAL10 gene expression. Surprisingly, the results of several experiments suggest that the TSF genes encode global regulatory factors. tsf1 to tsf6 mutations derepressed expression from yeast CYC-GAL hybrid promoters (fused to lacZ) that harbor a variety of operator sequences, and caused pleiotropic defects in cell growth, mating, and sporulation. S1 mapping and Northern blot results for tsf3 suggest that the molecular defect is at the transcriptional level. Mutant phenotypes were additive in certain combinations of tsf double mutants, implying that more than one silencing pathway is involved in TSF1 to TSF6 function. Most significantly, mutations in all six TSF1 to TSF6 genes activated expression from GAL1 and CYC1 promoters (fused to lacZ) lacking upstream activating sequences. Combined, the simplest interpretation of these results is that TSF1 to TSF6 encode factors that control the function of the basic RNA polymerase II transcriptional machinery.

emb-5, a gene required for the correct timing of gut precursor cell division during gastrulation in Caenorhabditis elegans, encodes a protein similar to the yeast nuclear protein SPT6

The emb-5 gene is required for the correct timing of division of gut precursor cells during gastrulation in Caenorhabditis elegans. We have now characterized the molecular structure of emb-5. The predicted emb-5-encoded protein (EMB-5) possesses an extremely acidic amino-terminus and overall similarity to the Saccharomyces cerevisiae nuclear protein SPT6, which has been shown to affect the transcription of a variety of genes and suggested to play a role in chromatin assembly or modification. EMB-5 may function in the control of cell cycle timing by modulating chromatin structure and consequently affects morphogenesis of C. elegans.

Molecular and genetic characterization of SPT4, a gene important for transcription initiation in Saccharomyces cerevisiae

Mutations in the SPT4 gene of Saccharomyces cerevisiae were isolated as suppressors of delta insertion mutations that interfere with adjacent gene transcription. Recent genetic evidence indicates that the SPT4 protein functions with two other proteins, SPT5 and SPT6, in some aspect of transcription initiation. In this work we have characterized the SPT4 gene and we demonstrate that spt4 mutations, like spt5 and spt6 mutations, cause changes in transcription. Using the cloned SPT4 gene, spt4 null mutations were constructed; in contrast to spt5 and spt6 null mutants, which are inviable, spt4 null mutants are viable and have an Spt- phenotype. The DNA sequence of the SPT4 gene predicts a protein product of 102 amino acids that contains four cysteine residues positioned similarly to those of zinc binding proteins. Mutational analysis suggests that at least some of these cysteines are essential for SPT4 function. Genetic mapping showed that SPT4 is a previously unidentified gene that maps to chromosome VII, between ADE6 and CLY8.

The CCR4 protein from Saccharomyces cerevisiae contains a leucine-rich repeat region which is required for its control of ADH2 gene expression

The CCR4 gene from Saccharomyces cerevisiae is required for the transcription of the glucose-repressible alcohol dehydrogenase (ADH2). Mutations in CCR4 also suppress the transcription at the ADH2 and his4-912delta loci caused by defects in the SPT10 (CRE1) and SPT6 (CRE2) genes. The CCR4 gene was mapped to the left arm of chromosome I and cloned by complementation of function using previously isolated segments of chromosome I. DNA sequence analysis of the cloned gene defined CCR4 as a 2511 bp open reading frame that would encode a polypeptide of 837 amino acids. The CCR4 mRNA was found to be 2.8 kb in size and Western analysis identified CCR4 as a 95,000 D protein. Disruption of the CCR4 gene resulted in reduced levels of ADH2 expression under both glucose and ethanol growth conditions and in temperature sensitive growth on nonfermentative medium, phenotypes essentially indistinguishable from previously identified mutations in CCR4. The amino terminus of the CCR4 protein was found to be rich in glutamine residues similar to a number of genes which are required for transcription. More importantly, CCR4 showed similarity to a diverse set of proteins sharing a leucine-rich tandem repeat motif, the presence of which has been implicated in mediating protein-protein interactions. Deletions of several of the five leucine-rich repeats in CCR4 were shown to produce nonfunctional proteins indicating the importance of the repeats to CCR4 activity. This leucine-rich repeat region may mediate the contact CCR4 makes with another factor.

Use of an epitope-tagged cDNA library to isolate cDNAs encoding proteins with nuclear localization potential

We have combined epitope tagging with an expression cDNA library in order to isolate cDNAs encoding nuclear proteins. This system allows us to detect proteins expressed from the cDNA library by using antibodies against the epitope tag. As a tag, we used the 85-aa N-terminal peptide of the SV40 T antigen which lacks the nuclear localization signal (NLS). A strong expression vector, pEF204 [Kim et al., Gene 91 (1990) 217-223], was modified into an epitope-tagging vector, pTkim, by putting the tag-coding region and a cDNA cloning site immediately after its promoter. From cDNA libraries constructed using pTkim, we isolated eight cDNA clones whose tagged proteins were localized within the nuclei. From partial sequence analysis, two cDNAs were shown to code for the ribosomal (r-) proteins, simian L44 and human L21, and the others were shown to be new. Furthermore, six cDNAs including those encoding the r-proteins could direct a non-karyophilic T antigen [Fischer-Fantuzzi et al., Virology 153 (1986) 87-95] into nuclei, showing that they have NLSs. These results indicate that this system is useful for isolating new cDNAs which code for nuclear proteins.

SPT4, SPT5 and SPT6 interactions: effects on transcription and viability in Saccharomyces cerevisiae

The SPT4, SPT5 and SPT6 genes of Saccharomyces cerevisiae were identified originally by mutations that suppress delta insertion mutations at HIS4 and LYS2. Subsequent analysis has demonstrated that spt4, spt5 and spt6 mutations confer similar pleiotropic phenotypes. They suppress delta insertion mutations by altering transcription and are believed to be required for normal transcription of several other loci. We have now analyzed interactions between SPT4, SPT5 and SPT6. First, the combination of mutations in any two of these three genes causes lethality in haploids. Second, some recessive mutations in different members of this set fail to complement each other. Third, mutations in all three genes alter transcription in similar ways. Finally, the results of coimmunoprecipitation experiments demonstrate that at least the SPT5 and SPT6 proteins interact physically. Taken together, these genetic and biochemical results indicate that SPT4, SPT5 and SPT6 function together in a transcriptional process that is essential for viability in yeast.

Homeotic protein binding sites, origins of replication, and nuclear matrix anchorage sites share the ATTA and ATTTA motifs

Nuclear matrix organizes the mammalian chromatin into loops. This is achieved by binding of nuclear matrix proteins to characteristic DNA landmarks in introns as well as proximal and distal sites flanking the 5' and 3' ends of genes. Matrix anchorage sites (MARs), origins of replication (ORIs), and homeotic protein binding sites share common DNA sequence motifs. In particular, the ATTA and ATTTA motifs, which constitute the core elements recognized by the homeobox domain from species as divergent as flies and humans, are frequently occurring in the matrix attachment sites of several genes. The human apolipoprotein B 3' MAR and a stretch of the Chinese hamster DHFR gene intron and human HPRT gene intron shown to anchor these genes to the nuclear matrix are mosaics of ATTA and ATTTA motifs. Several origins of replication also share these elements. This observation suggests that homeotic proteins which control the expression level of many genes and pattern formation during development are components of the nuclear matrix. Thus, the nuclear matrix, known as the site of DNA replication, might sculpture the crossroads of the differential activation of origins during development and S-phase and the control of gene expression and pattern formation in embryogenesis.

The yeast SUA7 gene encodes a homolog of human transcription factor TFIIB and is required for normal start site selection in vivo

Mutations in the Saccharomyces cerevisiae SUA7 gene were isolated as suppressors of an aberrant ATG translation initiation codon in the leader region of the cyc1 gene. Molecular and genetic analysis of the cloned SUA7 gene demonstrated that SUA7 is a single copy, essential gene encoding a basic protein (calculated Mr of 38,142) that is homologous to human transcription factor TFIIB. Analysis of cyc1 transcripts from sua7 strains revealed that suppression is a consequence of diminished transcription initiation at the normal start sites in favor of initiation at downstream sites, including a major site between the aberrant and normal ATG start codons. A similar effect was found at the ADH1 locus, establishing that this effect is not cyc1 gene-specific. Thus, SUA7 encodes a yeast TFIIB homolog and functions in transcription start site selection.

IMP2, a nuclear gene controlling the mitochondrial dependence of galactose, maltose and raffinose utilization in Saccharomyces cerevisiae

The IMP2 gene of Saccharomyces cerevisiae is involved in the nucleo-mitochondrial control of maltose, galactose and raffinose utilization as shown by the inability of imp2 mutants to grow on these carbon sources in respiratory-deficient conditions or in the presence of ethidium bromide and erythromycin. The negative phenotype cannot be scored in the presence of inhibitors of respiration and oxidative phosphorylation, indicating that the role of the mitochondria in the utilization of the above-mentioned carbon sources in imp2 mutants is not at the energetical level. Mutations in the IMP2 gene also confer many phenotypic alterations in respiratory-sufficient conditions, e.g. leaky phenotype on oxidizable carbon sources, sensitivity to heat shock and sporulation deficiency. The IMP2 gene has been cloned, sequenced and disrupted. The phenotype of null imp2 mutants is indistinguishable from that of the originally isolated mutant.

Glucose repression in the yeast Saccharomyces cerevisiae

Understanding the mechanism of glucose repression in yeast has proved to be a difficult and challenging problem. A multitude of genes in different pathways are repressed by glucose at the level of transcription. The SUC2 gene, which encodes invertase, is an excellent reporter gene for glucose repression, since its expression is controlled exclusively by this pathway. Genetic analysis has identified numerous regulatory mutations which can either prevent derepression of SUC2 or render its expression insensitive to glucose repression. These mutations allow us to sketch the outlines of a pathway for general glucose repression, which has several key elements: hexokinase PII, encoded by HXK2, which seems to play a role in the sensing of glucose levels; the protein kinase encoded by SNF1, whose activity is required for derepression of many glucose-repressible genes; and the MIG1 repressor protein, which binds to the upstream regions of SUC2 and other glucose-repressible genes. Repression by MIG1 requires the activity of the CYC8 and TUP1 proteins. Glucose repression of other sets of genes seems to be controlled by the general glucose repression pathway acting in concert with other mechanisms. In the cases of the GAL genes and possibly CYC1, regulation is mediated by a cascade in which the general pathway represses expression of a positive transcriptional activator.