In vivo system for characterizing clonal variation and tissue-specific gene regulatory factors based on function.

The inducibility of stably transfected alpha-cardiac actin genes differs among L cell clones. We examined the ability of muscle-specific factors to induce the expression of the human muscle alpha-cardiac actin gene promoter when stably transfected into mouse fibroblast L cells. This promoter is transcriptionally active in L cells at a low level, 2-5% of that in transfected muscle cells. Upon fusion with muscle cells to form heterokaryons, expression of the transfected alpha-cardiac actin gene promoter can be induced. However, induction is observed with only 10% of transfected L cell clones and the magnitude of this induction varies between 5- and 50-fold. These properties of the transfected L cell appear to be stably inherited. Our results are consistent with the hypothesis that muscle cells contain factors capable of increasing the transcription of the transfected gene, but that differences among L cell clones, possibly in the site of integration in the genome, determine the extent to which the gene can respond. By fusion into heterokaryons, transfectants with responsive genes can be identified. Such clones should prove useful in determining the basis for clonal variation. In addition, they provide an in vivo system for isolating functionally active tissue-specific transcription factors and the genes that encode them.

Genes coding for histone proteins in man are located on the distal end of the long arm of chromosome 7.

Tritium-labeled complementary RNA's to two cloned sea urchin DNA sequences, one coding for histones H1, H2B, and H4 and the other for H2A and H3, were hybridized in situ to high resolution human chromosomes. Evidence is presented showing that the histone genes in man are localized in bands q32-36 on the long arm of chromosome 7.

Myoblast transfer of human erythropoietin gene in a mouse model of renal failure.

Anemia is an invariable consequence of end-stage renal failure (ESRF) and recombinant erythropoietin has dramatically improved the quality of life of patients with ESRF. As an alternative approach, we developed a myoblast gene transfer system for the systemic delivery of human erythropoietin (EPO). We recently reported that transplantation of 4 x 10(7) cells of a C2 myoblast cell clone that stably secretes high level of functional human EPO, increased hematocrit from 44.6 +/- 3.0 to 71.2 +/- 7.9(%) in 2 wk, and the increase was sustained for at least 12 wk in nude mice. A renal failure model was created by a two-step nephrectomy in nude mice, and myoblasts were transplanted 3 wk after the second nephrectomy, when mean blood urea nitrogen level had increased from 26.3 +/- 6.1 to 85.4 +/- 24.0 (mg/dl) and the hematocrit had decreased from 45.2 +/- 2.7 to 33.9 +/- 3.7(%). After transplantation, the hematocrit markedly increased to 68.6 +/- 4.2(%) 2 wk, and to 68.5 +/- 4.0(%) 7 wk after the transplantation. Serum human EPO concentration determined by ELISA indicated a persistent steady EPO production from the transplanted muscle cells 8 wk after the transplantation. The fate of transplanted myoblasts in uremic mice was monitored by transplanting the EPO-secreting clone which had also been transduced with BAG retrovirus bearing the beta-galactosidase gene. 8 wk later, X-gal positive myofibers were detected in the entire transplanted area. The results demonstrate that myoblasts can be transplanted in uremic mice, and that myoblast gene transfer can achieve sufficient and sustained delivery of functionally active EPO to correct anemia associated with renal failure in mice.

Duplicated CArG box domains have positive and mutually dependent regulatory roles in expression of the human alpha-cardiac actin gene.

An upstream region from the transcription initiation site to -177 base pairs (bp) of the human alpha-cardiac actin gene directs the transient expression of a bacterial chloramphenicol acetyltransferase (CAT) gene only in muscle cells (A. Minty and L. Kedes, Mol. Cell. Biol. 6:2125-2136, 1986). We modified this promoter region by additional 5' deletions, linker-scanning mutations, and insertion-deletion mutations and demonstrated that the asymmetrical sequences in and adjacent to two CArG [for CC(A + T rich)6GG] motifs, located at -140 and -100 bp, play an important positive role in transcription. The significant impairment of transcriptional activity that accompanies the disruption of one CArG box region can be restored by either. This demonstrated that these two elements interact in a mutually dependent and similar manner. Furthermore, a DNA fragment that includes the CArG boxes had significant competitive activity for transcription directed by the alpha-cardiac actin promoter in an in vivo competition assay. We conclude that the two sequences around each CArG box may interact with the same class of trans-acting positive factor(s) and that these interactions may mediate muscle-specific expression. Each of the two CArG regions appears to be bound independently by such a positive factor(s), and the regions support high-level transcription in a synergistic manner. The transcriptional activity of this regulatory region is proportional to its distance from a TATA box (at -30 bp) and is strictly orientation dependent relative to the direction of transcription. Therefore this upstream region is not an enhancer but is a tissue-specific regulatory upstream element.

Upstream regions of the human cardiac actin gene that modulate its transcription in muscle cells: presence of an evolutionarily conserved repeated motif.

Transfection into cultured cell lines was used to investigate the transcriptional regulation of the human cardiac actin gene. We first demonstrated that in both human heart and human skeletal muscle, cardiac actin mRNAs initiate at the identical site and contain the same first exon, which is separated from the first coding exon by an intron of 700 base pairs. A region of 485 base pairs upstream from the transcription initiation site of the human cardiac actin gene directs high-level transient expression of the bacterial chloramphenicol acetyltransferase gene in differentiated myotubes of the mouse C2C12 muscle cell line, but not in mouse L fibroblast or rat PC-G2 pheochromocytoma cells. Deletion analysis of this region showed that at least two physically separated sequence elements are involved, a distal one starting between -443 and -395 and a proximal one starting between -177 and -118, and suggested that these sequences interact with positively acting transcriptional factors in muscle cells. When these two sequence elements are inserted separately upstream of a heterologous (simian virus 40) promoter, they do not affect transcription but do give a small (four- to fivefold) stimulation when tested together. Overall, these regulatory regions upstream of the cap site of the human cardiac actin gene show remarkably high sequence conservation with the equivalent regions of the mouse and chick genes. Furthermore, there is an evolutionarily conserved repeated motif that may be important in the transcriptional regulation of actin and other contractile protein genes.

Tsp transposons: a heterogeneous family of mobile sequences in the genome of the sea urchin Strongylocentrotus purpuratus.

In the preceding paper (J.B. Cohen, B. Hoffman-Liebermann, and L. Kedes, Mol. Cell. Biol., 5:2804-2813, 1985), we described the nucleotide sequence of ISTU4, which is a member of a new family of repetitive sequences, the Tsp family, present in a higher eucaryote, the sea urchin Strongylocentrotus purpuratus. We provided evidence that individual members of this family can act as transposable elements. Here we describe our structural analysis of the Tsp element family, which numbers about 1,000 members per haploid genome. Hybridization and nucleotide sequence analysis of several genomic Tsp clones demonstrate that structurally most Tsp elements resemble ISTU4. Tsp elements range in size up to about 1.3 kilobase pairs, have terminal domains that are conserved between the various examples studied, and contain a central portion of varying size, which may be extensively diverged. Structurally, however, the central portions are very similar and consist of several approximately 150-base-pairs-long, tandemly arranged, imperfect repeats, which are followed by a truncated repeat. The structural analysis is consistent with the possibility that the individual Tsp elements differ by multiples of these 150-base-pair repeats. One variant genomic clone has a solitary repeat and lacks the truncated repeat. The nucleotide sequences of different repeats of a single Tsp element can diverge extensively. The truncated repeat is divergent from most of the repeats, but in one case it is almost identical to a repeat of the same element. Comparison of the sequences from different elements enabled us to determine the boundaries of each structural domain and allows us to propose that each of these domains may be independent units of genetic information. Analysis of the population of Tsp-related sequences in the S. purpuratus genome by genomic blot hybridization suggests that most Tsp family members share the same overall structure. In addition, there is a structural element, about 70 base pairs long, that appears to interrupt the tandem arrangement of the 150-base-pair repeats at regular intervals.

Multiple 5'-flanking regions of the human alpha-skeletal actin gene synergistically modulate muscle-specific expression.

Transfection into myogenic and nonmyogenic cell lines was used to investigate the transcriptional regulation of the human alpha-skeletal actin gene. We demonstrated that 1,300 base pairs of the 5'-flanking region directed high-level transient expression of the bacterial chloramphenicol acetyltransferase gene in differentiated mouse C2C12 and rat L8 myotubes but not in mouse nonmuscle L.TK- and HuT-12 cells. Unidirectional 5' deletion analysis and heterologous promoter stimulation experiments demonstrated that at least three transcription-regulating subdomains lie in this 1,300-base-pair region. A proximal cis-acting transcriptional element located between positions -153 and -87 relative to the start of transcription at +1 was both sufficient and necessary for muscle-specific expression and developmental regulation during myogenesis in the two myogenic cell systems. The region 3' of position -87 interacted with factors present in both myogenic and fibroblastic cells and appeared to define, or to be a major component of, the basal promoter. In C2C12 myotubes, but not in L8 myotubes, a distal sequence domain between positions -1300 and -626 and the proximal sequence domain between positions -153 and -87 each induced transcription about 10-fold and synergistically increased CAT expression 100-fold over levels achieved by the sequences 3' of position -87. Furthermore, these cis-acting elements independently and synergistically modulated an enhancerless, heterologous simian virus 40 promoter in a tissue-specific manner. DNA fragments which included the proximal domain displayed classical enhancerlike properties. The central region between positions -626 and -153, although required in neither cell line, had a positive, two- to threefold, additive role in augmenting expression in L8 cells but not in C2C12 cells. This suggests that certain elements between positions -1300 and -153 appear to be differentially utilized for maximal expression in different myogenic cells and that the particular combination of domains used is dependent on the availability, in kind or amount, of trans-acting, transcription-modulating factors present in each cell type. Thus, multiple myogenic factors that vary qualitatively and quantitatively may be responsible for the different and complex modulatory programs of actin gene expression observed during in vivo muscle differentiation.

Identification of multiple proteins that interact with functional regions of the human cardiac alpha-actin promoter.

5' Sequences of the human cardiac alpha-actin gene are involved in the tissue-specific and developmental regulation of the gene. Deletion analyses combined with transient expression experiments in muscle cells have demonstrated three primary regions of functional importance (A. Minty and L. Kedes, Mol. Cell. Biol. 6:2125-2136, 1986; T. Miwa and L. Kedes, Mol. Cell. Biol. 7:2803-2813, 1987), and we have previously demonstrated binding of a protein indistinguishable from serum response factor (SRF) to the most proximal region (T.A. Gustafson, T. Miwa, L.M. Boxer, and L. Kedes, Mol. Cell. Biol. 8:4110-4119, 1988). In this report, we examine protein interaction with the remainder of the promoter. Gel shift and footprinting assays revealed that at least seven distinct nuclear proteins interacted with known and putative regulatory regions of the promoter. The transcription factor Sp1 bound to eight sites, as demonstrated by footprinting assays and gel shift analysis with purified Sp1. Purified CCAAT box-binding transcription factor CTF/NF-I and Sp1 were shown to interact with the far-upstream regulatory element at -410, and footprint analysis showed extensive overlap of these two sites. Two unidentified proteins with similar but distinct footprints interacted with the second region of functional importance at -140, which contains the second CArG motif [CC(A + T rich)6GG], and these proteins were shown to be distinct from SRF. SRF was found to bind to the remaining three CArG boxes, two of which were closely interdigitated with Sp1 sites. In addition, CArG box 4 was found to interact with SRF and another distinct protein whose footprint was contained within the SRF-binding site. Sequences surrounding the TATA box were also shown to bind proteins. Sp1 was shown to bind to a site immediately downstream from the TATA box and to a site within the first exon. Thus, each of the three functional upstream regions, as defined by transfection assays, was shown to interact with five factors: Sp1 and CTF/NF-I at the upstream site, two unidentified proteins at the central site, and SRF at the most proximal site. These results suggest that expression of the cardiac actin gene in muscle cells is controlled by complex interactions among multiple upstream and intragenic elements.

Two-level regulation of cardiac actin gene transcription: muscle-specific modulating factors can accumulate before gene activation.

We have previously proposed that the upstream regions of the human cardiac actin gene contain sequences that interact with muscle-specific factors with direct high-level transcription of this gene in differentiated muscle cells. In this study we showed that these factors already accumulate in the dividing myoblasts of the mouse C2C12 cell line before differentiation of the cells. The endogenous cardiac actin gene in the C2C12 line is expressed only at a low level in myoblasts but at a high level when these cells differentiate into multinucleate myotubes. In contrast, human cardiac actin genes stably introduced into C2C12 cells show high-level expression in both myoblasts and myotubes, indicating that the endogenous cardiac actin gene is repressed in myoblasts by a mechanism which does not affect transfected genes. In a second muscle cell line (the rat L8 cell line), the level of expression of transfected cardiac actin genes increases when these cells differentiate into myotubes, paralleling the expression of the endogenous sarcomeric actin genes. We suggest that the level of transcriptional modulating factors is low in L8 myoblasts and increases when these cells differentiate into myotubes. Our results demonstrate that at least two steps are necessary for high-level cardiac actin gene expression: activation of the gene and subsequent modulation of its transcriptional activity. Furthermore, the results indicate that the two regulatory steps can be dissociated and that the factors involved in modulation are distinct from those involved in gene activation.

The c-fos cyclic AMP-responsive element conveys constitutive expression to a tissue-specific promoter.

The c-fos and cardiac alpha-actin promoters share homologous 5' protein binding elements that are essential for serum-inducible and tissue-specific expression, respectively. Additional elements, auxiliary proteins or factor modifications, must distinguish the individual transcriptional responses of these two promoters. An element in the c-fos basal promoter that is normally responsible for transient stimulation of the fos gene in response to Ca2+ or cyclic AMP (CRE) may be able to modulate the expression of the upstream elements. We report here that this element, when inserted into the cardiac alpha-actin promoter, conveys constitutive expression to this otherwise highly restricted promoter. Additional data support the proposal that the CRE binding protein creates an alternative pathway whereby upstream regulatory elements in the cardiac alpha-actin promoter can activate transcription in a manner which circumvents the requirement for a tissue-specific environment.

Human cytoplasmic actin proteins are encoded by a multigene family.

We characterized nine human actin genes that we isolated (Engel et al., Proc. Natl. Acad. Sci. U.S.A. 78:4674-4678, 1981) from a library of cloned human DNA. Measurements of the thermal stability of hybrids formed between each cloned actin gene and alpha-, beta-, and gamma-actin mRNA demonstrated that only one of the clones is most homologous to sarcomeric actin mRNA, whereas the remaining eight clones are most homologous to cytoplasmic actin mRNA. By the following criteria we show that these nine clones represent nine different actin gene loci rather than different alleles or different parts of a single gene: (i) the restriction enzyme maps of the coding regions are dissimilar; (ii) each clone contains sufficient coding region to encode all or most of an entire actin gene; and (iii) each clone contains sequences homologous to both the 5' and 3' ends of the coding region of a cloned chicken beta-actin cDNA. We conclude, therefore, that the human cytoplasmic actin proteins are encoded by a multigene family.

Intramolecular regulation of MyoD activation domain conformation and function.

The MyoD family of basic helix-loop-helix (bHLH) proteins is required for myogenic determination and differentiation. The basic region carries the myogenic code and DNA binding specificity, while the N terminus contains a potent transcriptional activation domain. Myogenic activation is abolished when the basic region, bound to a myogenic E box, carries a mutation of Ala-114. It has been proposed that DNA binding of the MyoD basic region leads to recruitment of a recognition factor that unmasks the activation domain. Here we demonstrate that an A114N mutant exhibits an altered conformation in the basic region and that this local conformational difference can lead to a more global change affecting the conformation of the activation domain. This suggests that the deleterious effects of this class of mutations may result directly from defective conformation. Thus, the activation domain is unmasked only upon DNA binding by the correct basic region. Such a coupled conformational relationship may have evolved to restrict myogenic specificity to a small number of bHLH proteins among many with diverse functions yet with DNA binding specificities known to be similar.

Cardiac actin is the major actin gene product in skeletal muscle cell differentiation in vitro.

We examined the expression of alpha-skeletal, alpha-cardiac, and beta- and gamma-cytoskeletal actin genes in a mouse skeletal muscle cell line (C2C12) during differentiation in vitro. Using isotype-specific cDNA probes, we showed that the alpha-skeletal actin mRNA pool reached only 15% of the level reached in adult skeletal muscle and required several days to attain this peak, which was then stably maintained. However, these cells accumulated a pool of alpha-cardiac actin six times higher than the alpha-skeletal actin mRNA peak within 24 h of the initiation of differentiation. After cells had been cultured for an additional 3 days, this pool declined to 10% of its peak level. In contrast, over 95% of the actin mRNA in adult skeletal muscle coded for alpha-actin. This suggests that C2C12 cells express a pattern of sarcomeric actin genes typical of either muscle development or regeneration and distinct from that seen in mature, adult tissue. Concurrently in the course of differentiation the beta- and gamma-cytoskeletal actin mRNA pools decreased to less than 10% of their levels in proliferating cells. The decreases in beta- and gamma-cytoskeletal actin mRNAs are apparently not coordinately regulated.

Structure and unusual characteristics of a new family of transposable elements in the sea urchin Strongylocentrotus purpuratus.

The transposable element family TU of the sea urchin Strongylocentrotus purpuratus, a higher eucaryote, has recently been described (D. Liebermann, B. Hoffman-Liebermann, J. Weinthal, G. Childs, R. Maxson, A. Mauron, S.N. Cohen, and L. Kedes, Nature [London] 306:342-347, 1983). A member of this family, TU4, has an insertion, called ISTU4, of non-TU DNA. ISTU4 is a member of a family of repetitive sequences, which are present in some 1,000 copies per haploid S. purpuratus genome (B. Hoffman-Liebermann, D. Liebermann, L.H. Kedes, and S.N. Cohen, Mol. Cell. Biol. 5:991-1001, 1985). We analyzed this insertion to determine whether it is itself a transposable element. The nucleotide sequence of ISTU4 was determined and showed an unusual structure. There are four, approximately 150 nucleotides long, imperfect direct repeats followed by a single truncated version of these repeats. This region is bounded at either side by approximately 100-nucleotide-long sequences that are not related to each other or to the repeats. Nucleotide sequences at the boundaries of ISTU4-homologous and flanking regions in five genomic clones show that ISTU4 represents a family of sequences with discrete ends, which we call Tsp elements. We showed that the genomic locus that carries a Tsp element in one individual was empty in other individuals and conclude that Tsp elements are a new and different type of transposable element. Tsp elements lack two features common to most other transposable elements: Tsp integration does not result in the duplication of host DNA, and there are no inverted repeats at their termini, although short inverted repeats are present at a distance from the termini.

A common factor regulates skeletal and cardiac alpha-actin gene transcription in muscle.

The skeletal and cardiac alpha-actin genes are coexpressed in muscle development but exhibit distinctive tissue-specific patterns of expression. We used an in vivo competition assay and an in vitro electrophoretic mobility shift assay to demonstrate that both genes interact with a common trans-acting factor(s). However, there was at least one gene-specific cis-acting sequence in the skeletal alpha-actin gene that interacted with a trans-acting factor which was not rate limiting in the expression of the cardiac alpha-actin gene. The common factor(s) interacted with several cis-acting regions that corresponded to sequences that are required for the transcriptional modulation of these sarcomeric alpha-actin genes in muscle cells. These regulatory regions contained the sequence motif CC(A + T-rich)6GG, which is known as a CArG box. Results of in vivo competition assays demonstrated that the factor(s) bound by the skeletal alpha-actin gene is also essential for the maximal activity of the cardiac alpha-actin, simian virus 40 (SV40), alpha 2(I)-collagen, and the beta-actin promoters in muscle cells. In contrast, fibroblastic cells contained functionally distinct transcription factor(s) that were used by the SV40 enhancer but that did not interact with the sarcomeric alpha-actin cis-acting sequences. The existence of functionally different factors in these cell types may explain the myogenic specificity of these sarcomeric alpha-actin genes. Results of in vitro studies suggested that both the sarcomeric alpha-actin genes interact with the CArG box-binding factor CBF and that the skeletal alpha-actin promoter contains multiple CBF-binding sites. In contrast, CBF did not interact in vitro with a classical CAAT box, the SV40 enhancer, or a linker scanner mutation of an alpha-actin CArG box. Furthermore, methylation interference and DNase I footprinting assays demonstrated the precise sites of interaction of CBF with three CArG motifs at positions -98, -179, and -225 in the human skeletal alpha-actin gene.

Regulation of a human cardiac actin gene introduced into rat L6 myoblasts suggests a defect in their myogenic program.

The rat myogenic cell line L6E9 induces skeletal but not cardiac alpha-actin mRNA upon fusion to form myotubes. However, when a human cardiac alpha-actin gene was introduced into L6E9 myoblasts, differentiation of the cells led to the accumulation of human gene transcripts in parallel with those derived from the endogenous skeletal alpha-actin gene. This result demonstrates that factors which direct rat myogenesis can regulate a muscle gene from another species and that the L6E9 cells may have a defect in their ability to activate endogenous cardiac actin gene expression.

Human actin genes are single copy for alpha-skeletal and alpha-cardiac actin but multicopy for beta- and gamma-cytoskeletal genes: 3' untranslated regions are isotype specific but are conserved in evolution.

We have constructed isotype-specific subclones from the 3' untranslated regions of alpha-skeletal, alpha-cardiac, beta-cytoskeletal, and gamma-cytoskeletal actin cDNAs. These clones have been used as hybridization probes to assay the number and organization of these actin isotypes in the human genome. Hybridization of these probes to human genomic actin clones (Engel et al., Proc. Natl. Acad. Sci. U.S.A. 78:4674-4678, 1981; Engel et al., Mol. Cell. Biol. 2:674-684, 1982) has allowed the unambiguous assignment of the genomic clones to isotypically defined actin subfamilies. In addition, only one isotype-specific probe hybridizes to each actin-containing gene, with a single exception. This result suggests that the multiple actin genes in the human genome are not closely linked. Genomic DNA blots probed with these subclones under stringent conditions demonstrate that the alpha-skeletal and alpha-cardiac muscle actin genes are single copy, whereas the cytoskeletal actins, beta and gamma, are present in multiple copies in the human genome. Most of the actin genes of other mammals are cytoplasmic as well. These observations have important implications for the evolution of multigene families.

alpha-skeletal and alpha-cardiac actin genes are coexpressed in adult human skeletal muscle and heart.

We determined the actin isotypes encoded by 30 actin cDNA clones previously isolated from an adult human muscle cDNA library. Using 3' untranslated region probes derived from alpha-skeletal, beta- and gamma-actin cDNAs and from an alpha-cardiac actin genomic clone, we showed that 28 of the cDNAs correspond to alpha-skeletal actin transcripts. Unexpectedly, however, the remaining two cDNA clones proved to derive from alpha-cardiac actin mRNA. Sequence analysis confirmed that the two skeletal muscle alpha-cardiac actin cDNAs are derived from transcripts of the cloned alpha-cardiac actin gene. Direct measurements of actin isotype mRNA expression in human skeletal muscle showed that alpha-cardiac actin mRNA is expressed at 5% the level of alpha-skeletal actin. Furthermore, the alpha-cardiac actin gene expressed in skeletal muscle is the same gene which produces alpha-cardiac actin mRNA in the human heart. Of equal surprise, we found that alpha-skeletal actin mRNA accounts for about half of the total actin mRNA in adult heart. Comparison of total actin mRNA levels in adult skeletal muscle and adult heart revealed that the steady-state levels in skeletal muscle are about twofold greater, per microgram of total cellular RNA, than those in heart. Thus, in skeletal muscle and in heart, both of the sarcomeric actin mRNA isotypes are quite abundant transcripts. We conclude that alpha-skeletal and alpha-cardiac actin genes are coexpressed as an actin pair in human adult striated muscles. Since the smooth-muscle actins (aortic and stomach) and the cytoplasmic actins (beta and gamma) are known to be coexpressed in smooth muscle and nonmuscle cells, respectively, we postulate that coexpression of actin pairs may be a common feature of mammalian actin gene expression in all tissues.

Monocistronic transcription is the physiological mechanism of sea urchin embryonic histone gene expression.

We have examined histone gene expression during the early stages of sea urchin embryogenesis. The five histone genes expressed at that time are contained in tandem repetitive segments. It has been suggested that adjacent coding regions and their intervening spacer sequences are transcribed into large polycistronic messenger ribonucleic acid (RNA) precursors. We have subcloned into pBR322 deoxyribonucleic acid (DNA) sequences mapping either in the coding region, the 5' spacer, or the 3' spacer of the H2B histone gene. These clones were used to produce radioiodinated hybridization probes. We measured the steady-state quantity of H2B messenger RNA as well as spacer-specific RNA in the total RNA from embryos taken at various stages of development from fertilization to hatching of blastulae (0 to 22 h post-fertilization). Small amounts of RNA hybridizing to both spacer probes could be found. However, we show that these RNAs form mismatched hybrids with the spacer DNA and therefore cannot originate from the spacers present in the histone genes. We conclude that there is no detectable transcription of the spacer regions on either side of the H2B histone gene. The detection limit for RNA complementary to the 5' spacer sequence corresponds to a maximum of about three RNA molecules per cell, an amount shown to be far less than the projected steady-state pool size of a putative polycistronic transcript, if such a precursor were to be the obligatory transcript of the histone genes. (This conclusion was derived by using the known rates of production of H2B mRNA throughout early development [R. E. Maxson and F. H. Wilt, Dev. Biol., in press].) The physiologically relevant transcript of the histone genes in early development is therefore monocistronic and probably identical to the messenger RNA itself.

Regulation of the human cardiac/slow-twitch troponin C gene by multiple, cooperative, cell-type-specific, and MyoD-responsive elements.

The cardiac troponin C (cTnC) gene produces identical transcripts in slow-twitch skeletal muscle and in heart muscle (R. Gahlmann, R. Wade, P. Gunning, and L. Kedes, J. Mol. Biol. 201:379-391, 1988). A separate gene encodes the fast-twitch skeletal muscle troponin C and is not expressed in heart muscle. We have used transient transfection to characterize the regulatory elements responsible for skeletal and cardiac cell-type-specific expression of the human cTnC (HcTnC) gene. At least four separate elements cooperate to confer tissue-specific expression of this gene in differentiated myotubes; a basal promoter (between -61 and -13) augments transcription 9-fold, upstream major regulatory sequences (between -68 and -142 and between -1319 and -4500) augment transcription as much as 39-fold, and at least two enhancer-like elements in the first intron (between +58 and +1028 and between +1029 and +1523) independently augment transcription 4- to 5-fold. These enhancers in the first intron increase myotube-specific chloramphenicol acetyltransferase activity when linked to their own promoter elements or to the heterologous simian virus 40 promoter, and the effects are multiplicative rather than additive. Each of the major myotube regulatory regions is capable of responding directly or indirectly to the myogenic determination factor, MyoD.A MyoD expression vector in 10T1/2 cells induced constructs carrying either the upstream HcTnC promoter elements or the first intron of the gene 300- to 500-fold. Expression was inhibited by cotransfection with Id, a negative regulator of basic helix-loop-helix transcription factors. The basal promoter contains five tandem TGGGC repeats that interact with Sp1 or an Sp1-like factor in nuclear extracts. Mutational analysis of this element demonstrated that two of the five repeat sequences were sufficient to support basal level muscle cell-specific transcription. Whereas the basal promoter is also critical for expression in cardiac myocytes, the elements upstream of -67 appear to play little or no role. Major augmentation of expression in cardiomyocytes is also provided by sequences in the first intron, but these are upstream (between +58 and +1028). The downstream segment of the first intron has no enhancer activity in cardiomyocytes. A specific DNA-protein complex is formed by this C2 cell enhancer with extracts from C2 cells but not cardiomyocytes. These observations suggest that tissue-specific expression of the HcTnC gene is cooperatively regulated by the complex interactions of multiple regulatory elements and that different elements are used to regulate expression in myogenic and cardiac cells.