The ovalbumin gene region: common features in the organisation of three genes expressed in chicken oviduct under hormonal control

The Family Secrets of Avian Egg-Specific Ovalbumin and Its Related Proteins Y and X

The ovalbumin gene family in Gallus gallus is composed of three homologous genes located within a 46 kb locus on chromosome 2: ovalbumin, ovalbumin-related protein Y (OVAY), and ovalbumin-related protein X (OVAX) genes. The expression of these genes in hen oviduct is under estrogen control, but their relative hormonal responsiveness and subsequent protein concentration in egg, is distinctive. Interestingly, all three proteins lack the classical signal peptide for secretion. Ovalbumin, OVAX, and OVAY belong to the serine protease inhibitor (serpin) family whose members share a common tertiary structure. Ovalbumin and OVAX are one of the few members of this family that do not express any protease inhibition activity whereas OVAY has been predicted to be inhibitory, by comparison with the consensus sequence for inhibitory serpins. In contrast to ovalbumin and OVAY, OVAX interacts with heparin, a negatively charged glycosaminoglycan, via a positively charged domain exposed at the surface of the molecule. Ovalbumin is the major egg white protein and might be a source of amino acids for the developing embryo. The physiological function of OVAY is not known, but recent data have revealed a possible role of this protein in early embryonic development. Considering the antibacterial activities of OVAX, this protein might play a role in egg defense. This review sheds light on the expression, biochemistry, and structural specificities of these three highly similar paralogs. It gives new clues in favor of diverging functions, which are likely to have arisen by duplication events from a common ancestral gene.

Higher-Order Structural Determinants for Expression of the Ovalbumin Gene Family

The ovalbumin gene and the ovalbumin-related X and Y genes are expressed in the chicken oviduct in response to steroid hormones. These three genes are linked within a 100 kb domain of DNA which is preferentially sensitive to DNase I digestion in oviduct cell nuclei. No such preferential sensitivity to DNase is observed in nuclei isolated from other chicken tissues in which these genes are not transcribed. Thus, the DNase I sensitivity observed is correlated with the capacity for these genes to be expressed in oviduct. We have asked the question: are there specific signals in the DNA which are responsible for defining this domain or for conferring upon it the active, DNase I-sensitive, conformation? We have located DNA sequences belonging to a single repetitive DNA family, termed CR1, which are preferentially located in or near the boundary regions of the 100 kb domain. Therefore, these CR1 sequences are possible candidates for such a function. We have also searched for, but have not observed, any tissue-specific rearrangements of the DNA in the boundary regions of the domain. It is therefore unlikely that DNA rearrangements are involved in establishing the DNase I-sensitive domain in oviduct cells. However, we do note that a region at the far 3' end of the domain exhibits a cytidine methylation pattern which is highly variable among different chicken tissues. In particular, this region, which is approximately 30 kb downstream from the ovalbumin gene, is undermethylated in oviduct as compared to other hen tissues, and thus could be a control region involved in domain activation.

Avian transgenesis: progress towards the promise

The hen has long held promise as a low cost, high-yield bioreactor for the production of human biopharmaceuticals in egg whites. A typical egg white contains 3.5-4.0 grams of protein, more than half of which comes from a single gene (ovalbumin). Harnessing the power of the gene to express a recombinant protein could yield up to a gram or more of the protein in the naturally sterile egg. Accordingly, a major effort has been underway for more than a decade to develop robust methods for modification of the chicken genome. This effort intensified in the mid-1990s when several avian transgenic companies entered the scene. Progress has been made in that time but much remains to be done.

Organization and expression of multiple actin genes in the sea urchin

A set of at least 11 actin genes has been isolated from genomic recombinant deoxyribonucleic acid libraries of the sea urchin Strongylocentrotus purpuratus. Most of the isolates derive from a library which represents the genome of a single animal. There are at least five distinct types of sea urchin actin gene, some of which are represented by multiple copies in the genome. The actin gene types are distinguished by nonhomologous flanking sequences and intervening sequences, though the protein coding sequences appear in most cases to be quite similar. Eight of the 11 genes isolated have been recovered in lambda recombinants that contain two actin genes, linked at 5- to 9-kilobase distances. Restriction map overlaps suggest that the genome contains an array of at least three of these genes spaced over about 30 kilobases of deoxyribonucleic acid. In the linkage patterns observed, actin genes of diverse types were linked to each other. In early embryos, actin messenger ribonucleic acid (RNA) transcripts of 1.8 and 2.2 kilobases were found, and the longer of these transcripts was more prevalent in the maternal RNA of the egg. From RNA gel blot experiments, we conclude that the two transcripts derive from different actin gene types. Different repetitive sequences were located to either side of most of the actin genes, and in most observed cases the repeat sequences which were adjacent to actin genes of a given type were similar. The repeat sequences flanking the actin genes belonged to families which were transcribed, but those repeats in the neighborhood of the actin genes which have been investigated were not themselves represented in the stable RNAs of eggs or early embryos.

Use of the cosmid adenoviral vector cloning system for the in vitro construction of recombinant adenoviral vectors

The large size of the adenoviral genome unfortunately precludes there being many unique, useful restriction sites available for in vitro manipulation. Two methods have been developed for the construction of recombinant adenoviral vectors to date: in vivo homologous recombination or direct ligation in vitro. The efficiency of either the direct ligation method or the homologous recombination method is low because of the large size of the recombinant adenoviral vectors. To circumvent these problems, we have chosen to use the cosmid vector system to facilitate the assembly of recombinant adenoviral vectors. In this paper, we demonstrate for the first time that recombinant adenoviral vectors can be efficiently constructed in vitro by the cosmid vector system. With this method, it is possible to amplify the recombinant adenoviral vector DNA sufficiently to transfect 293 cells. The cosmid adenoviral vector cloning method for in vitro construction of the full-length recombinant adenoviral vectors represented here is simple and efficient and should facilitate the development of recombinant adenoviral vectors for human gene therapy.

Egg production and fertility in Drosophila depend upon the number of yolk-protein gene copies

The yolk proteins of Drosophila melanogaster comprise a family of three related yolk polypeptides each encoded by a single-copy gene. We show by genetic crosses that each gene makes an equivalent contribution to the fecundity and fertility of the female and they do not individually provide unique functions to the embryo. We show that the number of eggs laid by a female depends upon the number of genes encoding yolk polypeptides present in the genome and furthermore that the probability of an egg hatching into an adult also critically depends upon the number of yolk protein genes present in the mother. This suggests that the three yolk protein-encoding genes in Drosophila melanogaster may have arisen by duplication, then been maintained for quantitative reasons because they increased egg production and fertility, rather than each protein evolving a different function as is the case with most small gene families, such as tubulins and collagen genes.

Egg white proteins

1. Egg white proteins are the principal solutes present in egg white, making up approximately 10% of its weight. 2. They are globular proteins and most have acidic isoelectric points. 3. Many are glycoproteins with carbohydrate contents ranging from 2 to 58%. 4. Of the major egg white proteins, lysozyme is the only one having catalytic activity, but many have specific binding sites, e.g. for vitamins such as biotin, riboflavin and thiamin, or for metal ions such as FeIII. 5. A major group are those showing proteinase inhibitory activity, and they include ovomucoid, ovoinhibitor, cystatin and ovostatin. 6. The synthesis of egg white protein occurs in the oviduct, and is hormonally controlled either by oestrogens or progesterone. 7. Extensive studies have been carried out in the genes coding for egg white proteins.

Primary structure and assignment to chromosome 6 of three related rat genes encoding liver serine protease inhibitors

Three closely related SPI genes which encode highly homologous proteins of the serine protease inhibitor family secreted by rat liver (SPI-1, SPI-2 and SPI-3), were isolated from genomic libraries and sequenced, totally (SPI-2) or partially (SPI-1 and SPI-3). These genes all map on rat chromosome 6. Each of them spans about 10 kb and contains five exons separated by four introns, located at equivalent positions. S1 mapping analysis indicated that initiation of transcription occurs at the same position (tsp) in each of the three genes. In vitro transcription experiments demonstrated the presence of promoter elements upstream from the putative tsp. Detailed analysis of 5'-flanking sequences in the three SPI revealed major differences. A high degree of identity (70%) was found within a 350-bp region preceding the 'cap' site, with the exception of a 42-bp spacer, which was only found in SPI-3. Upstream from that point, SPI-1 and SPI-2 sequences remain largely homologous over at least 1 kb but completely diverge from the corresponding sequence in SPI-3. This may, at least partly, account for the differential regulation of the three SPI observed during acute inflammation and upon hypophysectomy.

Positive and negative regulatory elements control the steroid-responsive ovalbumin promoter

Steroid hormones regulate the transcriptional activity of the chicken ovalbumin gene both in vivo and in cell culture. To identify the regulatory elements involved, primary oviduct cell cultures were transfected with constructs containing the promoter and 5'-flanking region of the ovalbumin gene fused to the bacterial chloramphenicol acetyltransferase (CAT) gene. Induction of the OvCAT genes by estrogen, progesterone, or corticosterone mimics that of the endogenous ovalbumin gene, indicating that the transfected DNA is accurately regulated. Deletion analysis revealed that a steroid response element (SRE) resides between nucleotide coordinates -880 and -585 and that a negative regulatory element (NRE) resides between -350 and -248 in the ovalbumin gene. Thus, an NRE represses expression of the ovalbumin gene unless steroid hormones relieve this negative control through interactions involving a more distal SRE. Neither the SRE nor the NRE alone regulates the heterologous thymidine kinase promoter, suggesting either that they function as a single entity or that they are conditional regulatory elements. The NRE is functional in MCF-7 cells, but the SRE cannot be activated by steroids in this heterologous estrogen-responsive cell line. These data indicate that the steroid-receptor complex induces the ovalbumin gene through direct or indirect actions at an SRE to relieve represssion at an NRE.

Physical analysis of the CYC1-sup4 interval in Saccharomyces cerevisiae

CYC1 and sup4 are part of a tightly linked cluster of genes on chromosome X in the yeast Saccharomyces cerevisiae. Using as probes previously cloned fragments containing the CYC1 and sup4 genes, we have identified and cloned the deoxyribonucleic acid (DNA) present between these genes in one strain of yeast. We find that the CYC1 and sup4 genes are approximately 21 kilobases apart. In the same strain, the meiotic map distance is approximately 3.7 centimorgans, for a ratio of 5.6 kilobases per centimorgan in this interval. The physical mapping has allowed unambiguous determination of the orientation of CYC1 and sup4 relative to each other, the centromere, and a nearby transfer ribonucleic acid (tRNA(2Ser)) gene. The spontaneous mutation cyc1-1 inactivates the CYC1 gene as well as the neighboring loci OSM1 and RAD7. We have determined that a cyc1-1-bearing strain lacks approximately 13 kilobases of single-copy DNA from the CYC1-sup4 region, including all of the CYC1 coding information. There is a sequence homologous to the middle-repetitive element Ty1 at or near the breakpoint of the cyc1-1 deletion. We discuss the possibility that Ty elements play a role in the formation of such large, spontaneous deletions, which occur frequently in this region of chromosome X in certain yeast strains.

Molecular cloning of three structurally related genes for chicken avidin

The chicken genomic library was screened using the 32P-labelled 3'-end of avidin cDNA as a hybridization probe. A positive clone, lambda gAV12201, containing a 15-16 kb insert, was detected. The EcoRI subclones, pgAV0.4, pgAV1.8, pgAV3.3 and pgAV3.7 from the genomic clone were subjected to hybridization and restriction enzyme mapping analysis. The preliminary results suggest the existence of three structurally related genes for chicken avidin. Whether the natural gene is within the subclones can only be established when sequencing analyses of the subclones have been completed.

Reduced stability of RNA coding for yolk polypeptide 3 in Drosophila melanogaster ovary

In Drosophila three yolk polypeptides (YP1, YP2 and YP3) are synthesized at two sites in the adult female: in the fat body tissue, from which they are transported via the haemolymph to the ovary, and in the ovarian follicle cells which surround the developing oocytes. All three yolk polypeptides are synthesized at equal levels in the fat body. In this paper we show that the steady-state level of YP3 RNA is significantly reduced in the ovary in comparison with the fat body, and that none of the yolk protein genes is amplified either in the fat body or the follicle cells. In order to determine the basis of the reduced level of YP3 RNA in the ovary, which could result from a lower rate of transcription or through a decreased stability of the RNA, we have devised an in vivo method of determining relative rates of gene transcription. In both the fat body and the ovary all three yolk proteins are transcribed at similar rates. Thus we infer that YP3 RNA is destabilised in the ovary, accounting for the reduction in its steady-state level.

The mosaic genome of warm-blooded vertebrates

Most of the nuclear genome of warm-blooded vertebrates is a mosaic of very long (much greater than 200 kilobases) DNA segments, the isochores; these isochores are fairly homogeneous in base composition and belong to a small number of major classes distinguished by differences in guanine-cytosine (GC) content. The families of DNA molecules derived from such classes can be separated and used to study the genome distribution of any sequence which can be probed. This approach has revealed (i) that the distribution of genes, integrated viral sequences, and interspersed repeats is highly nonuniform in the genome, and (ii) that the base composition and ratio of CpG to GpC in both coding and noncoding sequences, as well as codon usage, mainly depend on the GC content of the isochores harboring the sequences. The compositional compartmentalization of the genome of warm-blooded vertebrates is discussed with respect to its evolutionary origin, its causes, and its effects on chromosome structure and function.

Conservation of the sizes for one but not another class of exons in two chick collagen genes

Type III collagen is often found in the same tissues as type I collagen, yet the function and nature of the fibrils formed by the two collagens differ markedly. To understand the evolutionary history of the collagen gene family in more detail, we isolated the gene for type III collagen and compared its structure with that of the gene for alpha 2(I) collagen. This comparison points to a remarkable conservation in the size distribution of the exons coding for the helical part of these two collagen polypeptides: equivalent amino acid segments in the helical domain of each polypeptide are encoded by exons of equal sizes in each gene. This suggests that after the interstitial collagen genes had been duplicated from a common ancestor about 2-5 X 10(8) years ago, no recombinations between these exons were tolerated, although the same recombinational phenomena must have played an important part in shaping the structure of the progenitor for these genes. This fixation of the size distribution of the exons which code for the interstitial collagen helical domains is found despite the persistence in these exons of sequence elements that should have favoured recombinational rearrangements, and contrasts with the variations in the pattern of sizes of some exons coding for the amino and carboxyl propeptides of these collagens.

Unequal activation by estrogen of individual Xenopus vitellogenin genes during development

Using a technique of filter hybridization under very stringent conditions to HindIII fragments of complementary DNA cloned in plasmids, we have measured the accumulation in hepatocytes of mRNA specified by each of the four vitellogenin genes (A1, A2, B1, B2) at different stages of development of Xenopus laevis. The ontogenic competence of embryonic liver to respond to the first exposure to estradiol-17 beta, in terms of activation of transcription of this multigene family, is acquired late in metamorphosis at around Nieuwkoop-Faber stage 58. Upon hormonal induction, the four mRNAs accumulate under non-steady-state conditions at different rates and to different extents at all developmental stages in vivo and in cultured adult hepatocytes. A1 and B1 mRNAs appear more rapidly and accumulate to levels that are five- to eightfold those specified by genes A2 and B2, with higher amounts of B1 than A1 mRNA. A threefold higher absolute rate of synthesis of A1 and B1 mRNAs in hepatocyte cultures, relative to the A2-B2 pair, suggests that hormonal regulation of differential accumulation of vitellogenin mRNA occurs at the transcriptional level. At the early developmental stages (up to stage 61) of acquired competence, there appears to be no fixed pattern of expression, but a pattern of unequal activation of individual genes of the Xenopus vitellogenin multigene family is established thereafter and then retained at all developmental stages of tadpoles, froglets, and in both male and female adults.

New cosmid vectors developed for eukaryotic DNA cloning

A series of ColE1 and pSC101 cosmid vectors have been constructed suitable for cloning large stretches of DNA. All contain a single BamHI site allowing cloning of Sau3A, MboI, BglII, BclI , and BamHI-generated fragments. These vectors have the following characteristics: (i) they are relatively small (1.7-3.4 kb); (ii) the BamHI cloning site is flanked by restriction enzyme sites enabling direct cloning of unfractionated insert DNA without generating multiple insert or vector ligation products [ Ish - Horowitz and Burke, Nucl . Acids Res. 9 (1981) 2989-2998]; (iii) two vectors ( pHSG272 and pHSG274 ) contain a hybrid Tn5 KmR/ G418R gene which is selectable in both prokaryotic and eukaryotic cells, making them suitable for transferring DNA into eukaryotic cells, and (iv) the different prokaryotic selectable markers available in the other vectors described facilitate cosmid rescue of the transferred DNA sequences from the eukaryotic cell: CmR, ApR, KmR, ( pHSG429 ), CmR, ( pHSG439 ), colicin E1 immunity ( pHSG250 ), (v) the cosmid pHSG272 was used successfully to construct a shuttle vector based on the BPVI replicon [ Matthias et al., EMBO J. 2 (1983) 1487-1492].

Expression of Drosophila heat-shock cognate genes during heat shock and development

The Drosophila genome contains a number of genes related to the major heat-shock-inducible (Hsp70) genes of Drosophila. The structure and expression of three of these heat-shock cognate (Hsc) genes have been studied; Hsc1 (previously described), Hsc2, and Hsc4 are dispersed on chromosome 3 at cytological loci 70C, 87D, and 88E, respectively. RNA homologous to Hsc4 was shown by hybridization selection translation experiments to encode a protein of approximately 70kd, with similar, but distinguishable, mobility to that of the heat-shock-inducible 70K protein. Because of variance in size of the 5' nonprotein coding region, it was possible to identify in adult flies distinct transcripts from each gene. Unlike transcripts from Hsp genes, the abundance of the Hsc transcripts was not increased after heat shock. Transcription of these Hsc genes is regulated during development. While transcripts from Hsc4 were equally abundant in RNA isolated from embryos, larvae and adults, Hsc1 and Hsc2 transcripts were not detected in embryo and larval RNA, and are therefore at least 20 times less abundant in these stages than in adults. The primary DNA sequences of the regions homologous to that encoding the amino terminus of hsp70 were compared. Approximately 76% homology of the base sequence and 78% homology of the deduced amino acid sequence were found among the four genes. The Hsp70 genes contain no intervening sequences; Hsc4 contains no insertions relative to Hsp70 in the region encoding the first 101 aa. However, in the codon specifying aa66 Hsc1 is interrupted by 1.7 kb of DNA; in the codon for aa55 Hsc2 contains an insertion of about 650 b. The sequences at the 5' and 3' junctions of the insertions in both Hsc1 and Hsc2 are similar to those found in intervening sequences of Drosophila and of many other organisms.

Sequence and linkage of the goat epsilon I and epsilon II beta-globin genes

Overlapping clones containing beta-globin genes have been isolated from a goat genomic library which establish the linkage arrangement 5'-epsilon I-epsilon II-psi beta X-beta C-3'. The complete nucleotide sequence of the epsilon I and epsilon II genes was determined. The sequences of these two genes, along with those previously reported for psi beta X and beta C, complete the sequence of the genes of this linkage set. The first gene in the quadruplet, epsilon I, shows unexpectedly high homology with the human epsilon globin gene both in coding and non-coding regions, and encodes a globin protein that is 90% homologous to human epsilon. The only major difference between the goat epsilon I gene and the human epsilon gene is the presence of an insertion element in the second intron of epsilon I. This element is repetitive in nature and is similar to those found in the second intron of the gamma, beta C and beta A globin genes of the goat. epsilon II also shows high nucleotide homology to the human epsilon globin gene in coding regions and encodes a protein 79% homologous to human epsilon. Notably, however, epsilon II has equivalent nucleotide homology in coding regions to the gamma and epsilon genes of the human locus. The insertion element present in epsilon I is not present in epsilon II. A comparison of the goat beta globin set described here, based on linkage arrangement, nucleotide homology and divergence analysis indicates that this subset of goat beta globin genes is analogous to the entire beta globin loci of other mammalian species. These analyses further indicate that the embryonic genes in these clusters are evolving more slowly than the adult beta globin genes. Comparison of the 5' flanking sequences of epsilon I and epsilon II with those of the beta-embryonic globin genes of other mammals reveals a conserved sequence, C-A-C-C-C-C-T-G, located 28 to 29 bases upstream from the C-C-A-A-T consensus sequence, which appears at this position in the embryonic genes, but in none of the non-embryonic genes. Significantly, this sequence is selectively conserved in the human alpha embryonic globin gene, zeta, which diverged from the beta embryonic genes 500 million years ago, and it may therefore represent an embryonic recognition or signal sequence.

The association of transcriptionally active genes with the nuclear matrix of the chicken oviduct

Eucaryotic DNA is organized into a series of supercoiled loops that are anchored to the nuclear matrix. When these DNA loops are cleaved by endonucleases, the DNA sequences which remain associated with the nuclear matrix can be recovered and analyzed for their content of specific genes. Using restriction endonucleases to cleave the loops, we demonstrate that ovalbumin and conalbumin gene sequences are preferentially associated with the nuclear matrix of hen oviduct cells but not with the nuclear matrix of hen brain cells. Furthermore, we determined that several regions of the ovalbumin gene were independently attached to the nuclear matrix of hen oviduct cells. This included sequences located 3.8 kb downstream from the 3' end of the ovalbumin gene transcription unit. To determine whether the nuclear matrix association of the ovalbumin gene was regulated by hormones, we examined the oviduct cells of chicks that underwent primary estrogen stimulation, estrogen withdrawal and secondary estrogen stimulation. Ovalbumin gene sequences selectively dissociated from the chick oviduct nuclear matrix during estrogen withdrawal and reassociated with the nuclear matrix following restimulation.

The distribution of CR1, and Alu-like family of interspersed repeats, in the chicken genome

We have studied the distribution of CR1, a family of short interspersed repeats, in the chicken genome; this family is homologous to the AluI family of man and to the B1-B2 families of mouse. Hybridization with a suitable probe showed that the vase majority of CR1 are located on the heaviest major component (1.708) of the genome which only represents 9% of chicken DNA. Some repeats were also found on the 1.702 and 1.704 components, but none on the 1.699 component (components are denoted by their buoyant densities in CsCl). The GC content of the repeats, 48%, matches that, 47%, of the major component mainly harboring it.

Vitellogenin B2 gene in Xenopus laevis: isolation, in vitro transcription and relation to other vitellogenin genes

The isolation of the four Xenopus laevis vitellogenin genes has been completed by the purification from a DNA library of the B2 gene together with its flanking sequences. The overlapping DNA fragments analyzed cover 34 kilobases. The B2 gene which has a length of 17.5 kilobases was characterized by heteroduplex and R-loop mapping in the electron microscope and by in vitro transcription in a HeLa whole-cell extract. Its structural organization is compared with that of the closely related B1 gene. The mRNA-coding sequence of about 6 kilobases is interrupted 34 times in the B1 gene and 33 times in the B2 gene. Sequence homology between the two genes was not only found in exons. In addition, 54% of the intron sequences as well as 63% and 48.5% respectively of the 5' and 3' flanking sequences, show enough homology to form stable duplexes. These findings are compared with earlier results obtained with the two other closely related members of the vitellogenin gene family, the A1 and the A2 genes.

On the evolution of multigene families

Multigene families are classified into three groups: small families as exemplified by hemoglobin genes of mammals; middlesize multigene families, by genes of mammalian histocompatibility antigens; and large multigene families, by variable region genes of immunoglobulins. Facts and theories on these evolving multigene families are reviewed, with special reference to the population genetics of their concerted evolution. It is shown that multigene families are evolving under continued occurrence of unequal (but homologous) crossing-over and gene conversion, and that mechanisms for maintaining genetic variability are totally different from the conventional models of population genetics. Thus, in view of widespread occurrence of multigene families in genomes of higher organisms, the evolutionary theory based mainly on change of gene frequency at each locus would appear to need considerable revision.

Actin gene family of Caenorhabditis elegans

Four actin genes have been isolated from Caenorhabditis elegans that account for all of the major actin hybridization to total genomic DNA. Actin genes I, II and III are clustered within a 12 X 10(3) base region; gene IV is unlinked to the others. All four genes have been sequenced from at least nucleotide -109 to +250. Genes I and III are identical for the first 307 coding nucleotides. Genes I and II differ in 14 positions within the first 250 coding nucleotides; one difference substitutes an aspartic acid for a glutamic acid at codon 5. Genes I and IV differ in 18 positions within the first 259 coding nucleotides without causing any amino acid differences. Genes I, II and III have introns after the first nucleotide of codon 64 and gene IV has an intron between codons 19 and 20. The four nucleotide sequences thus far define two different amino acid sequences. Both of the amino acid sequences resemble vertebrate cytoplasmic actin more than vertebrate muscle actin. A DNA polymorphism between the Bristol and Bergerac strains has been used as a phenotypic marker in genetic crosses to map the cluster of actin genes within a 2% recombination interval on linkage group V between unc-23 and sma-1 in order to begin a molecular genetic analysis of the actin loci.

Simultaneous analysis of conformation and transcription of A and B groups of vitellogenin genes in male and female Xenopus during primary and secondary activation by estrogen

In male Xenopus, primary estradiol administration results in noncoordinate activation in the liver of the A and B groups of vitellogenin genes, both as judged by transcription and DNase I sensitivity in isolated nuclei, B group genes being activated preferentially in the first 20 hr. Secondary induction in males or "primary" induction in females results in a coordinate and equal transcription of these two groups of genes. The elevated transcriptional activity following primary estrogen stimulation returns to low levels rapidly but the high DNase I sensitivity of these genes persists for 2-3 months. A non-coordinate activation of the A and B groups of vitellogenin genes is however re-established in response to a second administration of estradiol 8 months after primary stimulation of male Xenopus.

Isolation and characterisation of genes for androgen-responsive secretory proteins of rat seminal vesicles

Under the influence of testosterone, rat seminal vesicles synthesise large amounts of a tissue specific protein, S. Recombinant lambda clones have been isolated containing overlapping sequences covering a 27.5 kilo base region of the rat genome within which the gene for protein S is located. Recombinant plasmids bearing cDNA sequences for protein S were constructed in pBR328. One (pcS2) contains a 690 nucleotide insert and is probably full length. Detailed restriction maps of the S-gene are presented and the structure was confirmed by analysis of R-loops and heteroduplexes. The S-gene covers a 2 kbp region of the genome and consists of a 5' intron (490 bp) separating a leading exon (120 bp) containing the 5' untranslated region from a central exon (310 bp) containing most of the coding sequence and part of the 3' untranslated region. A larger intron (1100 bp) lies within the 3' untranslated region. The cloned gene is representative of the native gene but the S gene may be heterogeneous. Using pcS2, the hormonal control of S-specific mRNA was examined and a pronounced differential response to testosterone was observed.

Coordinate and non-coordinate estrogen-induced expression of A and B groups of vitellogenin genes in male and female Xenopus Hepatocytes in culture

The concentration of mRNA transcribed from A and B groups of vitellogenin genes, induced by estrogen added to primary cultures of hepatocytes from male and female adult Xenopus, was measured by a technique of filter disc hybridization with cloned Xenopus vitellogenin cDNA probes. In cells from naive male Xenopus (i.e. not previously exposed to hormone in vivo or in vitro), the two groups of the multigene family were non-coordinately expressed during the early stages of response to estradiol in vitro. Only B group transcripts could be detected for the first 2-3 h. At later times, or upon successive additions of estradiol to the male cell cultures, both A and B group mRNAs accumulated at the same rate and to the same extent. In female hepatocytes both groups of mRNAs accumulated in parallel at all stages of their response to estrogen, reaching levels 10-fold higher than in naive male cells similarly exposed to the hormone. However, hepatocytes from male Xenopus that had received a single injection of estradiol 5 weeks before the cells were prepared, now exhibited identical rates and extent of accumulation of A and B groups of vitellogenin mRNAs to those observed in female cells. Pulse-labeling of RNA in cultured male Xenopus hepatocytes confirmed that the coordinate and non-coordinate accumulation of mRNAs were largely a function of differential or equal transcription of the A and B groups of vitellogenin genes. A phenomenon analogous to the hormone-induced shift from non-coordinate to coordinate expression of two groups of genes of the same multigene family has not been described previously, and we discuss possible mechanisms underlying the transition.

DNA sequence preference of the progesterone receptor

Highly purified hen oviduct progesterone receptor A subunit was tested for binding to several chicken gene DNAs. Sequence preference detected by nitrocellulose filter adsorption of [32P]DNA fragments obtained from recombinant plasmids revealed a marked retention of certain DNA fragments. About a 10-fold preference was seen for DNA fragments flanking the 5' end of the steroid-regulated genes ovalbumin and gene Y. No preference was seen with analogous DNA fragments from chicken beta-globin and alpha-actin genes. Restriction endonuclease mapping suggests the presence of multiple receptor interaction sites flanking the 5' terminus of the ovalbumin gene. One of these preferential binding sites was localized between -135 and -247 base pairs upstream from the start of transcription. This region contains an 18-base-pair A + T-rich sequence, a likely candidate for the binding site itself, because earlier studies had shown receptor A to have marked preference for A + T-rich DNA.

Molecular structure and evolutionary origin of human cardiac muscle actin gene

Two recombinant phages that contain cardiac muscle actin gene were isolated from a human DNA library and their structures were determined. Restriction analysis indicates that both clones carry the same EcoRI 13-kilobase fragment where the coding sequence is mapped. The cloned DNA hybridized with polyadenylylated RNA from human fibroblasts, which directs the synthesis of cytoplasmic beta- and gamma-actin in vitro. However, sequence determination of the cloned DNA showed that the entire coding sequence perfectly matched the amino acid sequence of cardiac muscle actin. The initiation codon is followed by a cysteine codon that is not found at the amino-terminal site of any actin isoform, suggesting the necessity of post-translational processing for in vivo actin synthesis. There are five introns interrupting exons at codons 41/42, 150, 204, 267, and 327/328. Surprisingly, these intron locations are exactly the same as those of the rat skeletal muscle actin gene but different from those of nonmuscle beta-actin gene. Nucleotide sequences of all exon/intron boundaries agree with the G-T/A-G rule (G-T at the 5' and A-G at the 3' termini of each intron). The 3'-untranslated sequence has no homology to that of nonmuscle beta- or gamma-actin gene, but Southern blot hybridization has shown that this region has considerable homology to that of one of the other actin genes. These results indicate that the recombinant phages, which we have isolated, contain cardiac muscle actin gene and that cardiac muscle actin gene and skeletal muscle actin genes are derived from their ancestor gene at a relatively recent time in evolutionary development.

Assignment of snRNA gene sequences to the large chromosomes of rat kangaroo and chinese hamster isolated by flow cytometric sorting

Chromosomes from a rat kangaroo (Potorous tridactylus) cell line (PtK2) and from a Chinese hamster (Cricetulus griseus) cell line (CHV79) were isolated by means of fluorescence activated flow cytometric sorting. DAPI (4'-6-diamino-2-phenylindole) was used as the DNA specific fluorescent dye. The karyotype of the PtK2 cells which exhibits 13 chromosomes was separated into 6, and the 22 chromosomes of the CHV79 cells were resolved into 11 fractions. DNA extracted from these chromosomal fractions was used for restriction enzyme digestion and blotting on nitrocellulose filters. The blots were challenged with gene probes corresponding to ribosomal RNA (18S and 28S) and small nuclear RNA (U1-snRNA) genes. The rRNA genes were exclusively assigned to chromosomes containing the nucleolus organizing region (in PtK2: X chromosome; in CHV79: chromosomes 4, 5, 6, and 11). - Solely the largest chromosomes in both cell lines hybridized with U1-snRNA indicating that these gene sequences are located on those chromosomes only. Further possible genetic and biochemical applications of this experimental system are discussed.

The ovalbumin gene family: complete sequence and structure of the Y gene

The "ovalbumin Y" gene, one of three which constitute the ovalbumin gene family in chicken has been completely sequenced. The exact location of exons can be derived from the comparison with the ovalbumin gene sequence and from the map previously established by electron microscopy analysis. During evolution of the Y gene, selective pressure has operated to retain a sequence coding for an ovalbumin-like protein. The location of splice junctions, the length of protein coding exons and the reading phase are as in the ovalbumin gene. The overall homology between the Y and ovalbumin protein coding sequences is 72.6% (resulting in a 58% homology for the amino acid sequences). A significantly high number of base changes within coding sequences are present in clusters, which appear in several cases to be correlated with the occurrence of direct repeats. The 3' untranslated sequences of the Y and ovalbumin mRNAs have diverged much more, and the Y sequence contains a peculiar U(T) rich region. Corresponding introns of the ovalbumin and Y genes differ extensively both in sequence and in length. They share however characteristic biases in their base distribution.

Analysis of DNA attached to the chromosome scaffold

Two different methods have been described to investigate whether any specific DNA sequences are intimately associated with the metaphase chromosome scaffold. The chromosome scaffold, prepared by dehistonization of chromosomes with 2 M NaCl, is a nonhistone protein complex to which many looped DNA molecules are attached (Laemmli et al., 1977, Cold Spring Harbor Symp. Quant. Biol. 42:351--360). Chromosome scaffold DNA was prepared from dehistonized chicken MSB chromosomes by restriction endonuclease EcoRI digestion followed by removal of the looped DNA by sucrose gradient sedimentation. Alternatively, the scaffold DNA was prepared from micrococcal nuclease-digested intact chromosomes using sucrose gradients containing 2M NaCl. Solution hybridization of the radioactively labeled scaffold DNA with a large excess of total nuclear DNA revealed that, in either case, the scaffold DNA is not a unique sequence class of genomic DNA. Southern-blotting hybridization also showed that the scaffold DNA prepared from EcoRI-digested dehistonized chromosomes was not enriched (or depleted) in the ovalbumin gene sequences. The possibility of a dynamic interaction of protein and DNA in the chromosome scaffold and the possibility that the scaffold is a preparative artifact are discussed.

Identification of recombinant plasmids containing DNA sequences derived from the 3' end of ovine thyroglobulin mRNA

This paper describes the cloning in E. coli of several DNA copies of the 3' portion of ovine thyroglobulin mRNA. The cDNA clones were identified by in situ cloning hybridization to 32P-labelled thyroglobulin cDNA and by positive hybridization-translation assays. The longest thyroglobulin cDNA fragment cloned (psTg21A, 1670 bp), was shown by S1 nuclease mapping to be an unaltered copy of the thyroglobulin mRNA. psTg 21A overlapped with another cDNA fragment (psTg 11, 330 bp) containing the poly(dA)-tail and corresponding therefore to the 3' end of the mRNA. When aligned together the two clones represent more than 20% of the thyroglobulin mRNA length. Another cDNA fragment (psTg 15, 350 bp) was identified as an internal portion of the thyroglobulin mRNA sequence.

Localization of the casein gene family to a single mouse chromosome

A series of mouse-hamster somatic cell hybrids containing a variable number of mouse chromosomes and a constant set of hamster chromosomes have been used to determine the chromosomal location of a family of hormone-inducible genes, the murine caseins. Recombinant mouse cDNA clones encoding the alpha-, beta-, and gamma-caseins were constructed and used in DNA restriction mapping experiments. All three casein cDNAs hybridized to the same set of somatic cell hybrid DNAs isolated from cells containing mouse chromosome 5, while negative hybridization was observed to ten other hybrid DNAs isolated from cells lacking chromosome 5. A fourth cDNA clone, designated pCM delta 40, which hybridized to an abundant 790 nucleotide poly(A)RNA isolated from 6-d lactating mouse mammary tissue, was also mapped to chromosome 5. The chromosomal assignment of the casein gene family was confirmed using a mouse albumin clone. The albumin gene had been previously localized to mouse chromosome 5 by both breeding studies and analogous molecular hybridization experiments. An additional control experiment demonstrated that another hormone-inducible gene, specifying a 620 nucleotide abundant mammary gland mRNA, hybridized to DNA isolated from a different somatic cell hybrid line. These studies represent the first localization of a peptide and steroid hormone-responsive gene family to a single mouse chromosome.