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

Transcriptional involvement in neurotoxicity

Exposure to various chemicals and environmental hazards elicits changes in the expression of a variety of genes. The study of gene expression and transcriptional regulation is an important aspect of understanding the mechanisms associated with neurotoxicity. The availability of whole genome sequences and the development of new tools to identify and monitor transcriptional activity have accelerated the rate of discovery. This review surveys the historical steps taken to study gene expression in the brain and deals with recent advances in our understanding and classification of the roles of transcription factors. Disturbances in the regulation of gene expression associated with the neurotoxic response are also presented. Specific focus and detail is presented on the effects of heavy metals on the integrity and function of zinc finger proteins.

Brain non-adenylated mRNAs

Most eukaryotic messenger RNA (mRNA) species contain a 3'-poly(A) tract. The histone mRNAs are a notable exception although a subclass of histone-encoding mRNAs is polyadenylated. A class of mRNAs lacking a poly(A) tail would be expected to be less stable than poly(A)+ mRNAs and might, like the histones, have a half-life that varied in response to changes in the intracellular milieu. Brain mRNA exhibits an unusually high degree of sequence complexity; studies published ten years ago suggested that a large component of this complexity might be present in a poly(A)- mRNA population that was expressed postnatally. The question of the existence of a complex class of poly(A)- brain mRNAs is particularly tantalizing in light of the heterogeneity of brain cells and the possibility that the stability of these poly(A)- mRNAs might vary with changes in synaptic function, changing hormonal stimulation or with other modulations of neuronal function. The mRNA complexity analyses, although intriguing, did not prove the existence of the complex class of poly(A)- brain mRNAs. The observed mRNA complexity could have resulted from a variety of artifacts, discussed in more detail below. Several attempts have been made to clone members of this class of mRNA. This search for specific poly(A)- brain mRNAs has met with only limited success. Changes in mRNA polyadenylation state do occur in brain in response to specific physiologic stimuli; however, both the role of polyadenylation and de-adenylation in specific neuronal activities and the existence and significance of poly(A)- mRNAs in brain remain unclear.

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)

A procedure for purifying low-abundance protein components from the brain cytoskeleton-nuclear matrix fraction

We describe a preparative procedure for low-abundance proteins of the cytoskeleton-nuclear matrix fraction from frozen bovine brain. Strigent centrifugation and washing conditions in the preparation of the cytoskeleton-nuclear matrix fraction are avoided to minimize loss of nuclear material. A recently described horizontal isoelectric focusing column, which tolerates appreciable precipitation, is used. In concert with selection of urea concentration and temperature, this isoelectric focusing apparatus provides a new approach to the fractionation of this complex, relatively insoluble mixture of proteins and other components. In addition, a heated, sodium dodecyl sulfate-sizing column has been utilized in order to eliminate interactions between the desired low abundance proteins and more abundant contaminating proteins. Together these procedures purify a specific low-abundance protein sufficiently to be detected by Coomassie blue staining in two-dimensional gels. The methods are robust and can be applied to multiple, relatively large brain samples (150 g of crude grey matter per batch); thus they should facilitate partial peptide sequencing for brain proteins of this operational class.

Cloning of non-polyadenylated RNAs from rat brain

Rodent brain has been reported to contain a fraction of non-polyadenylated (poly(A)-) mRNA that includes about 100,000 different sequences, most of which are not found in the poly(A)+ fraction. We have prepared a cDNA library of low-abundance poly(A)- RNAs from rat brain polysomes, and have characterized three clones in detail. Two of the clones hybridize on Northern blots to poly(A)+ RNAs from brain. Dot blot hybridization and RNase protection assays demonstrate that although the bulk of the RNA complementary to these clones is present in the poly(A)- fraction, a small portion (7-21%) is present in the poly(A)+ fraction. Our results suggest that the poly(A)-mRNA fraction from rat brain may not contain sequences that are different from those in the poly(A)+ fraction.

Isolation of a specific cellular mRNA by subtractive hybridization in Theiler's virus persistent infection

Viruses change the mRNA repertoire of the tissues they infect. They add viral mRNAs and they specifically alter the expression of some host genes. These events can play important parts in pathogenesis. In principle, it should be possible to isolate viral mRNAs and to identify changes in host gene expression using subtractive hybridization. We tested this approach in the persistent infection of mouse central nervous system by Theiler's virus. A cDNA library was constructed with poly A+ RNA from infected mouse spinal cords. The library was screened with a subtracted probe. We identified one mitochondrial gene, coding for subunit 1 of cytochrome oxidase, which is overexpressed in infected tissues whereas another mitochondrial gene, URF 2, is not. Subtractive hybridization should prove to be invaluable in studying the pathogenesis of chronic human central nervous system diseases of unknown etiology.

Low-abundance 32-kilodalton nuclear protein specifically enriched in the central nervous system

Recently, a low-abundance nuclear protein, p32/6.3, has been identified in brain tissue (Egle and Shelton: Journal of Biological Chemistry 261:2294-2298, 1986). Using a Western blot procedure, we describe its distribution in the nervous system, determine its relative enrichment in brain versus liver, kidney, and certain other tissues, and describe an isolation procedure from brain. Selective enrichment occurs in basal ganglia, diencephalon, hippocampus, cerebellum, brainstem, spinal cord, and cerebral cortex but not in retina, dorsal root ganglia, and sympathetic ganglia. Thus, enrichment is limited to areas of the central nervous system. p32/6.3 appears to be preferentially enriched in neurons, because in bulk-isolated fractions from rat grey matter it is more abundant in neuron-enriched fractions than in astrocyte-enriched fractions. p32/6.3 is approximately 20-fold more concentrated in an insoluble nuclear protein or matrix fraction from forebrain than from kidney, liver, adrenal gland, or retina. This degree of enrichment is an ancient trait, detectable in the chicken as well as mammals.

Forebrain-enriched RNAs of the canary: a population analysis using hybridization kinetics

Canaries and other songbirds offer unique advantages for analyzing the relationship between specific gene regulation and neural plasticity. To establish a quantitative profile of the population of RNAs potentially involved in this regulation, we analyzed the solution hybridization kinetics of canary forebrain cytoplasmic polyadenylated RNA. Hybridization of forebrain cDNA to forebrain RNA provides evidence for RNA species at individual concentrations ranging from less than 10(-6) to about 10(-3) (by fractional mass). Cross-hybridization to RNA from the rest of the brain, together with other studies, defines a subpopulation of about 5000 rare RNAs that are enriched in the forebrain compared to the rest of the brain. Some of these forebrain-enriched RNAs are likely to play a role in regulating the neural plasticity characteristic of the canary forebrain.

Probes for rare mRNAs reveal distributed cell subsets in canary brain

cDNA clones of 7 low-abundance canary brain RNAs hybridize in situ to different subsets of brain cells. Although these cell sets are distinct, they are dispersed in a variety of brain regions with overlapping anatomical distributions. These cDNA clones were initially selected by their relative hybridization to forebrain and rest-of-brain RNAs and represent a sampling of a much larger population of differentially expressed RNAs present at individual concentrations of 10(-7) to 10(-4) as a fraction of polyadenylated RNA mass. Our results suggest the existence of several thousand low-abundance brain mRNAs likely to be distributed in diverse and overlapping brain cell subsets. Furthermore, our experiments define a simple and general strategy for producing and analyzing molecular probes for subsets of brain cells and provide an initial set of useful reagents for further study of brain organization and development.

Isolation and regional mapping of DNA sequences unique to human chromosome 21

To isolate DNA sequences unique to chromosome 21 we have used a recombinant-DNA library, constructed from a mouse-human somatic-cell hybrid line containing chromosome 21 as the only human chromosome. Individual recombinant phage containing human DNA inserts were identified by their hybridization to total human DNA sequences and by their failure to hybridize to total mouse DNA sequences. A repeat-free human DNA fragment was then subcloned from each of 14 such recombinant phage. An independent somatic-cell hybrid was used to assign all 14 subcloned fragments to chromosome 21. Thirteen of the fragments have been regionally mapped using a somatic-cell hybrid containing a human 21 translocation chromosome. Two probes map proximal to the 21q21.2 translocation breakpoint, and 11 probes map distal to this breakpoint, placing them in the region 21q21.2-21q22. One of seven probes used to screen for restriction-fragment-length polymorphisms recognized polymorphic DNA fragments when hybridized to genomic DNA from unrelated individuals. These 14 unique probes provide useful tools for studying the structure and function of human chromosome 21 as well as for investigating the molecular biology of Down syndrome.

A simple nonisotopic method for restriction mapping in single-stranded DNA cloning vectors based on taking timepoints during primed Klenow synthesis

A fast, simple, and nonisotopic method for restriction mapping inserts in single-stranded cloning vectors (such as M13 or single-stranded plasmids) is presented. The procedure uses a commercially available oligonucleotide sequencing primer to initiate Klenow-mediated, unidirectional DNA synthesis along the single-stranded insert DNA. Aliquots taken at very short timepoints from this reaction are quick-frozen, heat-inactivated, and restriction-digested with the restriction enzyme or enzymes of interest. When the samples are run on an agarose gel and stained with ethidium bromide, the restriction bands appear in the order of their proximity to the priming site. The method's advantages are that it is fast, unidirectional and thus relatively unambiguous, requires neither isotope nor elaborate DNA handling or extraction procedures, and resolves the ambiguities due to "near doublets" that often plaque double-digest mapping and partial-digest mapping. Tetranucleotide restriction maps extending up to 5 kb can be determined from a single priming experiment; more infrequent hexanucleotide restriction sites can be mapped over longer distances. Also, a single aliquot taken at an early timepoint can be restriction-digested to establish the orientation of cloned inserts.

The low incidence of multiple sclerosis in areas near the equator may be due to ultraviolet light induced suppressor cells to melanocyte antigens

It has been shown by Elmets et al. (1) that ultraviolet irradiation of the skin followed by the application of a normally sensitizing antigen results in tolerance induction to the antigen. This tolerance is due to the induction of suppressor T-cells specific for the antigen. Multiple sclerosis is more common in certain climates distant from the equator where there is less ultraviolet light (sunlight). I postulate that people near the equator are exposed to more sunlight and that the ultraviolet light from the sunlight aids in the induction of suppressor cells specific for melanocyte associated antigens. Since melanocytes are of neural crest origin and share antigenic determinants with neural tissues these suppressor cells may act to protect against multiple sclerosis which is probably an autoimmune disease directed against neural tissues.

In situ hybridization--visualization and quantitation of genetic expression in mammalian brain

In situ hybridization techniques have been developed that quantitate the relative levels of specific mRNAs in individual cell types of a heterogeneous tissue, the mammalian brain. Here, we discuss those special procedures and precautions necessary for hybridizing radiolabeled probes to developing and adult brain mRNAs. The probes discussed include double-stranded recombinant DNA, as well as single-stranded DNA, RNA, and polyuridylate. We detail the procedure for determining the relative numbers of hybrids formed and computing the ratio of specific mRNAs to total polyadenylated mRNA and discuss the importance of this ratio for comparison of relative levels of specific mRNAs within and among cell types in an individual brain or between brains.