Hybridization of ribonucleic acid with unique sequences of mouse deoxyribonucleic acid

Strategies for identifying genes that play a role in spinal cord regeneration

A search for genes that promote or block CNS regeneration requires numerous approaches; for example, tests can be made on individual candidate molecules. Here, however, we describe methods for comprehensive identification of genes up- and down-regulated in neurons that can and cannot regenerate after injury. One problem concerns identification of low-abundance genes out of the 30,000 or so genes expressed by neurons. Another difficulty is knowing whether a single gene or multiple genes are necessary. When microchips and subtractive differential display are used to identify genes turned on or off, the numbers are still too great to test which molecules are actually important for regeneration. Candidates are genes coding for trophic, inhibitory, receptor and extracellular matrix molecules, as well as unknown genes. A preparation useful for narrowing the search is the neonatal opossum. The spinal cord and optic nerve can regenerate after injury at 9 days but cannot at 12 days after birth. This narrow window allows genes responsible for the turning off of regeneration to be identified. As a next step, sites at which they are expressed (forebrain, midbrain, spinal cord, neurons or glia, intracellular or extracellular) must be determined. An essential step is to characterize proteins, their levels of expression, and their importance for regeneration. Comprehensive searches for molecular mechanisms represent a lengthy series of experiments that could help in devising strategies for repairing injured spinal cord.

The Drosophila brain revisited by enhancer detection

The patterns of gene expression in the Drosophila brain were studied by using the lacZ reporter gene carried on an enhancer detector element. From the analysis of serial sections of the heads of 6000 enhancer detector lines, reporter gene expression in some lines was found to generally follow boundaries established by cell type or anatomy, revealing distinct patterns of lacZ expression restricted to the lamina, the medulla, mushroom bodies, antennal lobes, or other anatomical subdivisions. About 15% of the lines showed ubiquitous expression in most or all head tissues and 25% of the lines showed expression throughout the CNS. Another quarter of the lines showed widespread expression in the CNS, with large regions of the brain showing expression. This suggests that the majority of detected genes are expressed with little spatial specificity. The expression patterns produced by 12 different insertions at the rutabaga locus were found to be extremely similar in the brain and offer strong evidence that the enhancer detector elements generally report the activity of an adjacent gene. Only 15% of the lines were judged to have relatively specific expression in one brain region, including those with preferential or specific expression in the mushroom bodies, antennal lobes, lamina, medulla, etc. The cytological insertion sites for elements showing preferential mushroom body expression were found to be dispersed in the genome at approximately 50 different chromosomal regions. In addition to providing a broad picture of the transcriptional activity in the Drosophila brain, these enhancer detector lines offer access to interesting new genes and form a novel collection of lines in which identifiable brain cells are marked in a reproducible way.

Novel brain-specific bovine cDNA for a developmentally regulated mRNA encoding a putative new member of the leucine-rich glycoprotein (LRG) family

We have isolated a bovine cDNA which hybridized to a 2 kb mRNA specifically expressed in the rat and human brain. The mRNA was abundantly expressed in adult but not 21-week old human brain. In the rat brain, there was very little of the transcript in 15-day old fetus but it increased in abundance with development, being most abundant in the adult and expressed in all brain regions. Genomic analysis showed that the sequence is single copy and conserved in all vertebrates examined, including chicken. The 702 bp partial cDNA encoded an amino acid sequence for a putative member of the leucine-rich glycoprotein (LRG) family known to be involved in cell adhesion/recognition. The predicted polypeptide displayed sequence identity with that recently reported for the human oligodendrocyte-myelin glycoprotein. This cDNA should prove useful in further investigations on brain-specific cell-cell interactions.

Gene expression in cells of the central nervous system

This review summarized a part of our studies over a long period of time, relating them to the literature on the same topics. We aimed our research toward an understanding of the genetic origin of brain specific proteins, identified by B. W. Moore and of the high complexity of the nucleotide sequence of brain mRNA, originally investigated by W. E. Hahn, but have not completely achieved the projected goal. According to our studies, the reason for the high complexity in the RNA of brain nuclei might be the high complexity in neuronal nuclear RNA as described in the Introduction. Although one possible explanation is that it results from the summation of RNA complexities of several neuronal types, our saturation hybridization study with RNA from the isolated nuclei of granule cells showed an equally high sequence complexity as that of brain. It is likely that this type of neuron also contains numerous rare proteins and peptides, perhaps as many as 20,000 species which were not detectable even by two-dimensional PAGE. I was possible to gain insight into the reasons for the high sequence complexity of brain RNA by cloning the cDNA and genomic DNA of the brain-specific proteins as described in the previous sections. These data provided evidence for the long 3'-noncoding regions in the cDNA of the brain-specific proteins which caused the mRNA of brain to be larger than that from other tissues. During isolation of such large mRNAs, a molecule might be split into a 3'-poly(A)+RNA and 5'-poly(A)-RNA. In the studies on genomic DNA, genes with multiple transcription initiation sites were found in brain, such as CCK, CNP and MAG, in addition to NSE which was a housekeeping gene, and this may contribute to the high sequence complexity of brain RNA. Our studies also indicated the presence of genes with alternative splicing in brain, such as those for CNP, MAG and NGF, suggesting a further basis for greater RNA nucleotide sequence complexity. It is noteworthy that alternative splicing of the genes for MBP and PLP also produced multiple mRNAs. Such a mechanism may be a general characteristic of the genes for the myelin-specific proteins produced by oligodendrocytes. In considering the high nucleotide sequence complexity, it is interesting that MAG and S-100 beta genes etc. possess two additional sites for poly(A).(ABSTRACT TRUNCATED AT 400 WORDS)

Gene expression in different cell types of aging rat brain

"Bound" and "free" RNA polymerase activities were assessed in the nuclear fraction of cerebral cortical, neuronal, astroglial, and oligodendroglial cells obtained from rats of young, adult, and old ages. Significant decreases in both the bound and free polymerase II activities were noticed in old brain, as compared to adult brain, in neuronal and oligodendroglial nuclei. In astroglia, only the free polymerase II was found to be affected. No effect of aging could be seen on the activity of bound RNA polymerase I + III. The free RNA polymerase I + III activity was increased from adult to old age in neuronal nuclei, but unchanged in oligodendroglial and astroglial nuclei. The age-dependent reduction in RNA polymerase II was maximum in oligodendroglial cells, whereas it was least, although still significant, in neuronal cells. DNA isolated from old brain was unable to enhance the transcriptional activity when added to chromatin preparations obtained from rat brains of any of the above ages and the "old" chromatin was unable to accept even the "young" DNA as additional exogenous template. It is concluded that the reduced gene expression noticed in old brain nuclei is due to both altered chromatin/DNA structure and inadequate levels of free RNA polymerase II.

Genetic causes of mental handicap and opportunities for prevention

Prior to 1970 nearly one half of severe mental handicap (IQ less than 50) was unexplained and genetic causes were recognized in one third of all patients. In recent years the genetic contribution has risen to 50%, with the decline in importance of environmental causes and the growing recognition of X-linked forms of mental retardation and chromosomal microdeletion syndromes. Recognition of genetic conditions is vital for accurate assessment of recurrence risks and in order, in some instances, to provide specific prenatal diagnosis. With full utilization of existing prenatal screening procedures and a more detailed family history, severe mental handicap due to genetic conditions should be reduced by 30-40%.

Expression and developmental regulation of two unique mRNAs specific to brain membrane-bound polyribosomes

Translation in vitro of membrane-bound polyribosomal mRNAs from rat brain has shown several to be developmentally regulated [Hall & Lim (1981) Biochem. J. 196, 327-336]. Here we describe the isolation and characterization of cDNAs corresponding to two such brain mRNAs. One cDNA (M444) hybrid-selected a 0.95 kb mRNA directing the synthesis in vitro of a 21 kDa pI-6.3 polypeptide, which was processed in vitro by microsomal membranes. A second cDNA (M1622) hybridized to a 2.2 kb mRNA directing the synthesis of a 55 kDa pI-5.8 polypeptide. Both mRNAs were specific to membrane-bound polyribosomes. Restriction maps of the corresponding genomic DNA sequences are consistent with both being single copy. The two mRNAs were present in astrocytic and neuronal cultures, but not in liver or spleen or in neuroblastoma or glioma cells. The two mRNAs were differently regulated during brain development. In the developing forebrain there was a gradual and sustained increase in M444 mRNA during the first 3 weeks post partum, whereas M1622 mRNA appeared earlier and showed no further increase after day 10. In the cerebellum the developmental increase in M444 mRNA was biphasic. After a small initial increase there was a decrease in this mRNA at day 10, coincident with high amounts of M1622 mRNA. This was followed by a second, larger, increase in M444 mRNA, when amounts of M1622 mRNA were constant. The contrasting changes in these two mRNAs in the developing cerebellum are of particular interest, since they occur during an intensive period of cell proliferation, migration and altering neural connectivity. As these mRNAs are specific to differentiated neural tissue, they represent useful molecular markers for studying brain differentiation.

Cloning of DNA corresponding to rare transcripts of rat brain: evidence of transcriptional and post-transcriptional control and of the existence of nonpolyadenylated transcripts

To examine the expression of genes encoding rare transcripts in the rat brain, we have characterized genomic DNA clones corresponding to this class. In brain cells, as in all cell types, rare transcripts constitute the majority of different sequences transcribed. Moreover, when compared with other tissues or cultured cells, brain tissue may be expected to have an even larger set of rare transcripts, some of which could be restricted to subpopulations of neural cells. We have identified seven clones whose transcripts are nonabundant, averaging less than three copies per cell. Clone rg13 (rat genomic 13) RNA was detected only in the brain, whereas RNA of a second clone, rg40, was also detected in the brain and in a melanoma. Transcripts of rg13 were found in cerebellum, cerebral cortex, and regions underlying the cortex, whereas rg40 transcripts were not detected in the cerebellum. Transcripts of both rg13 and rg40 were found in pelleted polysomal RNA. RNA of another clone, rg34, was found in the brain, liver, and kidney but was found in pelleted polysomal RNA only in the brain, suggesting that its expression may be post-transcriptionally controlled. The remaining four clones represent rare transcripts that are common to the brain, liver, and kidney; rg18 RNA is restricted to the nucleus, whereas rg3, rg26, and rg36 transcripts are found in the cytoplasm of all three tissues. Transcripts of the brain-specific clone, rg13, and the commonly expressed clone, rg3, are nonpolyadenylated, presumably belonging to the high-complexity, nonpolyadenylated class of transcripts in the mammalian brain.

Cloning of DNA corresponding to rare transcripts of rat brain: evidence of transcriptional and post-transcriptional control and of the existence of nonpolyadenylated transcripts

To examine the expression of genes encoding rare transcripts in the rat brain, we have characterized genomic DNA clones corresponding to this class. In brain cells, as in all cell types, rare transcripts constitute the majority of different sequences transcribed. Moreover, when compared with other tissues or cultured cells, brain tissue may be expected to have an even larger set of rare transcripts, some of which could be restricted to subpopulations of neural cells. We have identified seven clones whose transcripts are nonabundant, averaging less than three copies per cell. Clone rg13 (rat genomic 13) RNA was detected only in the brain, whereas RNA of a second clone, rg40, was also detected in the brain and in a melanoma. Transcripts of rg13 were found in cerebellum, cerebral cortex, and regions underlying the cortex, whereas rg40 transcripts were not detected in the cerebellum. Transcripts of both rg13 and rg40 were found in pelleted polysomal RNA. RNA of another clone, rg34, was found in the brain, liver, and kidney but was found in pelleted polysomal RNA only in the brain, suggesting that its expression may be post-transcriptionally controlled. The remaining four clones represent rare transcripts that are common to the brain, liver, and kidney; rg18 RNA is restricted to the nucleus, whereas rg3, rg26, and rg36 transcripts are found in the cytoplasm of all three tissues. Transcripts of the brain-specific clone, rg13, and the commonly expressed clone, rg3, are nonpolyadenylated, presumably belonging to the high-complexity, nonpolyadenylated class of transcripts in the mammalian brain.

Changes in gene expression during postnatal development of the rat cerebellum

The base sequence complexity of total and polysomal poly(A +)RNA from rat cerebellum was measured during postnatal development by RNA-DNA hybridization. At saturation, total and polysomal poly(A +)RNA from neonate cerebellum hybridized to 12.7% and 5.0% of the single-copy genomic DNA, respectively. Assuming asymmetric transcription, the sequence complexity of these RNA populations is sufficient to code for greater than 100,000 different gene transcripts. The percentage of single-copy DNA expressed as total and polysomal poly(A +)RNA declined during postnatal development, reaching adult values of 10.0% and 4.1%, respectively. These results indicate that cerebellar maturation is accompanied by significant reductions in the diversity of genetic information expressed in the tissue.

High mobility group nonhistone chromosomal proteins of the developing sea urchin embryo

The high mobility group or HMG proteins are nonhistone chromosomal proteins that have been found in relatively high amounts in nuclei of many tissues. A number of studies have shown that some of these proteins are preferentially associated with actively transcribed regions of the genome and may play a role in maintaining these regions in an active state. In this study, we undertook an investigation of the high mobility group proteins from the sea urchin, Stronglyocentrotus purpuratus. Initially the putative sea urchin HMGs were extracted from isolated nuclei of hatching blastula-stage embryos with 5% perchloric acid (PCA). The major proteins in this extract were characterized according to their electrophoretic mobility, amino acid composition, and association with isolated deoxyribonucleoprotein particles. The results indicate there is only one "major" sea urchin HMG protein, termed P2 in this paper. An estimate of the amount of P2 in relation to the inner histones, however, was low compared to what has been found for other HMG proteins. Of the other major 5% PCA-extractable proteins, one was identified as the cleavage stage H1. Another protein apparently resulted from H3 contamination in the 5% PCA extract, and the fourth major protein did not have all the characteristics of an HMG. In particular, it was not found associated with nucleosomal particles. The HMG proteins from other developmental stages were then examined. Five percent PCA extracts of nuclei from unfertilized eggs, 2-cell, 16-cell, hatching blastula, gastrula, and pluteus stages were analyzed on SDS- and acetic acid-urea gels. This analysis indicated that P2 exists in two different forms differing slightly in charge. The less basic form was found in the egg, 2-cell and 16-cell extracts. At the hatching blastula stage, both forms were present and by pluteus stage, the more basic form predominated. It appears that P2 is undergoing a developmental change from a less to more basic form. The presence of P2 in the 5% PCA extract of egg nuclei is proof that P2 does not initially appear sometime during embryogenesis but is already in the egg nucleus prior to fertilization.

Genetic expression in the developing brain

The adult mouse brain contains complex populations of polyadenylated [poly(A)+] and nonpolyadenylated [poly(A)-] messenger RNA's (mRNA's). These mRNA's are separate sequence populations, similar in complexity, and in combination are equivalent to approximately 150,000 different mRNA sequences, of average length. Essentially all of the "adult" poly(A)+ mRNA's are present in the brain at birth. In contrast, most of the poly(A)- mRNA's are absent. Brain poly(A)- mRNA's begin to appear soon after birth, but the full adult complement is not reached until young adulthood. This suggests that these poly(A)- mRNA's specify proteins required for the biological capabilities of the brain that emerge during the course of postnatal development.

Analysis of brain and pituitary RNA metabolism: a review of recent methodologies

Recent characterization of brain and pituitary RNA metabolism is reviewed. Relative to other tissues, the brain transcribes more of the unique, single-copy DNA. This transcriptional diversity reflects the inherent heterogeneity in organization and development of the brain. The end product of transcriptional regulation in the brain is a population of functional cytoplasmic mRNAs with multiple components, differing in complexity and abundance. Analysis of nuclear and cytoplasmic RNA provides evidence that both brain-specific synthesis and processing may determine the final mRNA population. Both polyadenylated and non-polyadenylated RNA classes contribute significantly to the total brain polysomal mRNA fraction. Characterizations of individual species of mRNA from both brain and pituitary are described. One possible transcriptional modulator in both the pituitary and brain is the presence of steroid hormone at responsive sites. Functional consequences of steroid accumulation within the brain may be (1) interactions with neurotransmitter, especially catecholamine, metabolism and function, (2) developmental interactions with neuronal systems, and (3) differentiation of glial cell function. The pleiotropic nature of steroid hormone effects (both transcriptional and non-transcriptional) within one brain region is considered by examining the biochemical effects of glucocorticoids in the hippocampus.

Amount and distribution of 5-methylcytosine in human DNA from different types of tissues of cells

Analysis of the total base composition of DNA from seven different normal human tissues and eight different types of homogeneous human cell populations revealed considerable tissue-specific and cell-specific differences in the extent of methylation of cytosine residues. The two most highly methylated DNAs were from thymus and brain with 1.00 and 0.98 mole percent 5-methylcytosine (m5C), respectively. The two least methylated DNAs from in vivo sources were placental DNA and sperm DNA, which had 0.76 and 0.84 mole percent m5C, respectively. The differences between these two groups of samples were significant with p less than 0.01. The m5C content of DNA from six human cell lines or strains ranged from 0.57 to 0.85 mole percent. The major and minor base composition of DNA fractionated by reassociation kinetics was also determined. The distribution of m5C among these fractions showed little or no variation with tissue or cell type with the possible exception of sperm DNA. In each case, nonrepetitive DNA sequences were hypomethylated compared to unfractionated DNA.

Developmental changes in the composition of polyadenylated RNA isolated from free and membrane-bound polyribosomes of the rat forebrain, analysed by translation in vitro

Free and membrane-bound polyribosomes were isolated from the rat forebrain during its development. Polyadenylated RNA [poly(A)+ RNA] was isolated from both fractions, by using oligo(dT)-cellulose chromatography, and its composition studied by translating the poly(A)+ RNA in vitro in reticulocyte lysates. Electrophoretic analysis of the translation products showed that both free and membrane-bound polyribosomal poly(A)+ RNA gave many common components, but that there were also distinct differences in the protein composition of the products of the two fractions. Several proteins, of mol.wts. 39 000, 37 000, 31 000, 27 000 and 17 000, appeared to be products predominantly of free polyribosomal poly(A)+ RNA, whereas others, of mol.wt. 47 000, 33 000, 24 000 and 21 000 were specific to the membrane-bound polyribosomal poly(A)+ RNA fraction. More developmental changes were observed in the translational products of the membrane-bound poly(A)+ RNA fraction. Proteins of mol.wts. 33 000 and 21 000, which were predominant components of the translational products of this fraction when isolated from 10-day and older rats, were not present in translational products derived from preparations isolated from 3-day-old rats. The developmental appearance of these proteins as translational products of the membrane-bound poly(A)+ RNA suggests the appearance of new mRNA species. These transcriptional changes are discussed in relation to processes involved in brain differentiation, including myelination.

Developmental changes in the protein and ribonucleic acid components of rat brain messenger ribonucleic acid-protein particles isolated from free polyribosomes by oligo(dT)-cellulose chromatography

A study has been made of the developmental changes that occur in the RNA and protein moieties of mRNA-protein particles isolated from newborn and adult rat forebrain free polyribosomes. mRNA-protein particles were isolated by oligo(dT)-cellulose chromatography from salt-washed polyribosomes dissociated by puromycin/0.5 M-KCl treatment as two fractions (E1 and E2) by using Tris/HCl/NaCl eluting buffers containing respectively 25 and 50% (v/v) formamide. Isopycnic centrifugation on CsCl gradients showed that the newborn-derived fractions E1 and E2 has buoyant densities of 1.48--1.50 and 1.41--1.43 g/cm3. Adult-derived E1 and E2 fractions had corresponding values of 1.47 and 1.42 g/cm3. The pooled mRNA-protein particles from the E1 and E2 fractions after deproteinization with proteinase K sedimented with a mean size of approx. 18 S on a sucrose gradient containing 85% formamide with little differences between mRNA molecules from newborn and adult. The mean lengths of the poly(A) segments were similar, being about 130 nucleotides long. Distinct changes were found in the protein composition of the mRNA-protein particles. Fractions E1 and E2 from the newborn contained two major proteins of mol.wts. 74 000 and 52 000 with differences in the relative proportions in each fraction. In contrast, adult fractions E1 and E2 contained predominantly the larger protein. However, the adult fraction E2 contained a more heterogeneous population of minor bands of proteins, including that of mol.wt. 52 000. The findings are discussed briefly in relation to other changes in the developing brain.

Segregation of rapidly acetylated histones into a chromatin fraction released from intact nuclei by the action of micrococcal nuclease

It has been previously shown that micrococcal nuclease digestion and subsequent fractionation of hen oviduct nuclei generates fractions enriched (first supernatant fraction - 1SF) and depleted (second supernatant fraction - 2SF) in ovalbumin genes, while a third fraction, the pellet fraction, contains about the same level of this gene as whole chromatin (Bloom and Anderson (1978) Cell 15, 141-150). We have utilized this fractionation method in an attempt to assess the extent and kinetics of histone acetylation associated with chromatin from the 1SF, 2SF, and pellet fraction. Hepatoma Tissue Culture (HTC) cells were labelled for 30 minutes in vivo with 3H-acetate, nuclei isolated and the chromatin fractionated. The specific activity of the histones in the 1SF was slightly greater than that of the 2SF (1.2 to 1.6 fold difference) independent of the length of nuclease digestion. If the labelling period is followed by short (10 to 60 minute) treatment of the cells with sodium butyrate, the more rapidly as well as more extensively acetylated histones are also preferentially found in the 1SF. This is in part the result of segregation of chromatin particles into the 1SF as the histones associated with these particles become hyperacetylated. That is, the extent of histone acetylation regulates the distribution of chromatin in the 1SF, 2SF and pellet fraction.

Extensive homology of nuclear ribonucleic acid and polysomal poly(adenylic acid) messenger ribonucleic acid between normal and neoplastically transformed cells

A cell line, designated BP6T, derived from Syrian hamster embryo (SHE) cells following treatment with benzo[a]pyrene is capable of producing tumors in newborn hamsters following the injection of as few as 1-10 cells. Polysomal poly(A) mRNA and total nuclear RNA obtained from this highly tumorigenic cell line were compared to RNAs obtained from the nonneoplastic parental embryo cells by a variety of techniques. RNA excess hybridizations to normal cell radiolabeled single-copy DNA or to a single-copy DNA tracer enriched for sequences transcribed in neoplastically transformed cells were unable to detect any significant differences in RNA sequence complexity between normal SHE cells and neoplastic BP6T cells. This finding of extensive homology of polysomal poly(A) mRNA and total nuclear RNA between normal and neoplastic cells, together with our previous finding of extensive homology of the major 35S-labeled nuclear or cytoplasmic polypeptides observable on two-dimensional gels [Leavitt, J. C., & Moyzis, R. K. (1978) J. Biol. Chem. 253, 2497-2500], demonstrates that the phenotypic changes associated with neoplastic transformation by chemical carcinogens are accompanied by relatively few changes in the qualitative pattern of gene expression in cells cultured in vitro.

Corticosterone effects on rat brain template active region chromatin

The effect of prenatal exposure to corticosterone on brain chromatin was examined. Pregnant Fischer inbred rats were administered corticosterone or saline on Days 17 and 18 of gestation and their offspring examined at 0 (day of birth), 2, 3, 4 or 6 days of age. In utero exposure to corticosterone was associated with a 24 hr delay of a developmental peak in the percentage of brain template active region chromatin. Brain and body weights of the steroid and saline-treated animals were similar, but corticosterone led to a temporary decrease in body and brain weight at 2 days of age which was reversed at 6 days of age. These results of these studies suggest an impact of corticosterone on brain gene expression.

Irreversible gene repression model for control of development

As the pluripotent cells of early embryos differentiate, each progressively loses the potency to develop into several phenotypes. Ultimately, each cell becomes irreversibly restricted to the expression of a single phenotype. Although in many instances details regarding those restriction events are well known, there is little information concerning the nature of the gene transcription changes involved. A model that accounts for the diminution of developmental potential as resulting from progressive, irreversible repression of previously active genes is presented. A scheme of progressive gene repression, rather than selective gene activation, is most consistent with observations from experimental embryology as well as from more recent biochemical experimentation.

Complexity of poly(A+) and poly(A-) polysomal RNA in mouse liver and cultured mouse fibroblasts

RNA excess hybridization experiments were used to measure the complexity of nuclear RNA, poly(A+) mRNA, poly(A-) mRNA, and EDTA-released polysomal RNA sedimenting at less than 80 S in mouse liver and in cultured mouse cells. With both cell types, poly(A-) RNA was found to contain 30-40% of the sequence diversity of total mRNA. In the case of liver this represents 5,700 poly(A-) molecules and 8,600 poly(A+) molecules for a total of approximately 14,300 different mRNAs. Comparison of the complexity of mRNA with that of nuclear RNA revealed that in liver and in cultured cells, mRNA has only 10-20% of the sequence diversity present in nuclear RNA. This latter observation is consistent with existing data on mammalian cells from this and other laboratories.

Complexity of nuclear and polysomal polyadenylated RNA in a pluripotent embryonal carcinoma cell line

The base-sequence complexities and relative abundance of polysomal and nuclear polyadenylated [poly(A+)] RNA sequences have been analyzed in a pluripotent embryonal carcinoma cell line. Polysomal RNA and nuclear poly(A+) RNA have a complexity representing respectively 0.5% and 2.5% of the single copy component of haploid mouse DNA (1.8 X 10(6) K base pairs). By hybridization with specific cDNAs, three abundance classes were found in polysomal poly(A+) RNA, representing respectively 31%, 33%, and 36% of the RNA, with base sequence complexities of 0.1 X 10(3), 0.9 X 10(3), and 14.5 X 10(3) kilobases. This corresponds to 7000-8000 different mRNA species of an average length of 2000 nucleotides, present on an average of 5 to 600 copies per cell. In nuclear RNA, a major class of abundance was found with a complexity of 100 X 10(3) kilobases, each sequence being present in 1 copy per nucleus. The majority of the polysomal poly(A+) RNA sequences are represented in the nuclear poly(A+) RNA but are present in a more restricted range of relative abundance implying posttranscriptional mechanisms of quantitative modulation: polysomal RNA sequences appear to be preferentially transcribed into nuclear cDNA suggesting a preferential location of these sequences close to poly(A) sequences. The presence of a specialized gene product, globin specific RNA, could not be detected either in the nuclear or polysomal compartments of embryonal carcinoma cells, even at levels that would have detected one sequence per 50 cells.

Localization of the globin gene in the template active fraction of chromatin of Friend leukemia cells

Friend leukemia cell chromatin has been fractionated into template active and inactive components. The globin gene sequence is associated with the template active component both prior to and after the cells are induced with dimethyl sulfoxide to synthesize hemoglobin and therefore appears to be in an active configuration in uninduced as well as in induced Friend leukemia cells. In cells which have lost the ability to produce hemoglobin, the globin gene sequence is not associated with the template active fraction of chromatin. These results demonstrate the success of the fractionation procedure.

Enrichment for the globin coding region in a chromatin fraction from chick reticulocytes by endonuclease digestion

A nuclease-sensitive fraction was obtained from chick reticulocyte chromatin by brief digestion with an endonuclease (DNAase II, deoxyribonucleate 3'-oligonucleotidohydrolase, EC 3.1.4.6). The nuclease-sensitive fraction typically contained less than 1% of the chromatin-DNA but about 50% or more of the nascent chromatin-bound RNA. Hybridization of chick globin complementary DNA to the DNA component of the nuclease-sensitive fraction of reticulocyte chromatin indicated a 3--5 fold enrichment for the globin coding region of the chromatin. The control experiment utilizing DNA from a nuclease-sensitive fraction of chick liver chromatin did not show a comparable enrichment for the globin coding region. This suggests that the endonuclease-effected enrichment for the globin coding region in the nuclease-sensitive fraction of reticulocyte chromatin is to some degree specific for structural genes transcribed in reticulocytes.

Organization and transcriptional activity of brain chromatin subunits

Digestion of brain nuclei with micrococcal nuclease produces 11.2-S chromatin subunits which comprise up to 80% of the total nuclear DNA. Hybridization studies with excess subunit DNA demonstrate that subunits are distributed throughout the repeated and nonrepeated sequences of the genome. No class of nonrepeated DNA appears to be excluded from subunits. Transcribed DNA is present in chromatin subunits since in vitro labelled poly(A+)-mRNA hybridizes to excess subunit DNA with kinetics identical to that for total DNA.

Frequency distribution of messenger sequences within polysomal mRNA and nuclear RNA from rat liver

DNA complementary to polysomal poly(A)-containing mRNA (cDNA) of male rat liver was used to study the diversity of messenger sequences in the nucleus and in polysomes. 1. Hybridization of cDNA against an excess of its own polysomal mRNA template revealed that about 10,000 different mRNA species are expressed in the liver tissue. They are distributed in a wide frequency range derived from approximately 0.5% of the total genome. 2. Hybridization of the cDNA against total nuclear RNA shows that messenger sequences comprise less than 1% of the mass of total nuclear RNA. Messenger sequences have a different frequency distribution in nucleus and cytoplasm. 3. In hybridizations using cDNA, which had been fractionated into sequences representing abundant and scarce polysomal mRNA molecules, it was found that although abundant cytoplasmic messenger sequences are also abundant in the nucleus, they exist in a significantly lower frequency range in the nuclear compartment.

Renaturation kinetics of cDNA complementary to cytoplamic polyadenylated RNA from rainbow trout testis. Accessibility of transcribed genes to pancreatic DNase

We have determined the fraction of polyadenylated cytoplasmic RNA from trout testis complementary to unique and repetitive DNA. Some 21% of the cDNA probe representative of this RNA population renatures with rapid kinetics, characteristics of repetitive sequences. The major proportion of the cDNA renatures with unique sequence DNA. Experiments with fractionated cDNA probes allow us to conclude that, in trout testis, the most abundant polyadenylated mRNAs are not preferentially transcribed from repetitive DNA, as it has shown to be the case in two eukaryotic cell lines. Treatment of trout testis nuclei with DNase I, under conditions in which 10% of the total DNA is digested, preferentially depletes the DNA of sequences being transcribed into polyadenylated mRNA. These data confirm the results of H. Weintraub and M. Groundine [(1976) Science 193, 848-856] and those of A. Garel and R. Axel [(1976) Proc. Natl. Acad. Sci. U.S.A. 73, 3966-3970] and suggest that the conformation of DNA in the active genes of chromatin is such that it is more susceptible to digestion by DNaseI.