Genes encoding neuronal nicotinic acetylcholine receptors

Four genes (alpha 2, alpha 3, alpha 4, and beta 2), which encode proteins homologous to the Torpedo electric organ and vertebrate muscle nicotinic acetylcholine receptors, have been identified by cloning rat brain cDNAs. Injection of transcripts derived from these cDNAs into Xenopus laevis oocytes results in the formation of three nicotinic acetylcholine receptors. Two of these receptors, alpha 3/beta 2 and alpha 4/beta 2, have the characteristics of ganglionic nicotinic receptors. The third (alpha 2/beta 2) exhibits a previously undescribed pharmacology and thus represents a novel subtype that may be expressed in the brain. The wide distribution of alpha 2, alpha 3, alpha 4, and beta 2 transcripts in the brain indicates that neuronal nicotinic acetylcholine receptors are a major neurotransmitter receptor system.

Coordinate regulation of RNAs encoding two isoforms of the rat muscle nicotinic acetylcholine receptor beta-subunit

The nicotinic acetylcholine receptor (nAchR) mediates communication between nerve and skeletal muscle. The properties, levels and distribution of these receptors change during development of the neuromuscular junction. These changes may be due, in part, to expression of different gene products. We are using nuclease protection experiments and cDNA cloning to identify the RNA transcripts that encode nAchRs in rat muscle. This analysis has identified two beta-subunit mRNAs. Complementary DNAs corresponding to these two RNAs have been isolated from a rat skeletal muscle cDNA library. Based on nucleotide sequence analysis, these RNAs differ by 9 bases in their 5' coding sequence. The levels of both mRNAs change similarly during muscle development and upon denervation of adult skeletal muscle. These two beta-subunit-RNAs probably result from the use of different exon/intron splice sites in the beta-subunit gene.

Distribution and possible metabolic role of class III alcohol dehydrogenase in the human brain

In human brain, the sole alcohol dehydrogenase (ADH) present in significant quantity has been shown to be Class III (chi) ADH and this ADH is ineffective in generating potentially toxic and reactive acetaldehyde from ethanol at concentrations attainable in living brain tissue. We have extended this finding to show that Class I ADH potentially present is undetectable even when concentrated several hundred-fold. Purified Class III ADH from human brain is identical in its pattern of tryptic peptides and in other properties to Class III ADH from human liver. Immunohistochemical staining and western immunoblots using polyclonal antibodies reveal that Class III ADH is widely distributed in brian and most concentrated in the subependymal layer and perivascular areas. Class III ADH closely resembles omega-hydroxyfatty acid dehydrogenase and a possible role for the brain enzyme is in the oxidation of long chain fatty alcohols and omega-hydroxyfatty acids.

Identification of a novel nicotinic acetylcholine receptor structural subunit expressed in goldfish retina

A new non-alpha (n alpha) member of the nicotinic acetylcholine receptor (nAChR) gene family designated GFn alpha-2 has been identified in goldfish retina by cDNA cloning. This cDNA clone encodes a protein with structural features common to all nAChR subunits sequenced to date; however, unlike all known alpha-subunits of the receptor, it lacks the cysteine residues believed to be involved in acetylcholine binding. Northern blot analysis shows multiple transcripts hybridizing to the GFn alpha-2 cDNA in goldfish retina but undetectable levels of hybridizable RNA in brain, muscle, or liver. S1 nuclease protection experiments indicate that multiple mRNAs are expressed in retina with regions identical or very similar to the GFn alpha-2 sequence. In situ hybridization shows that the gene encoding GFn alpha-2 is expressed predominantly in the ganglion cell layer of the retina.

A shortened synthesis of 4-(3-aminopropyl) pyrazole, an affinity ligand for alcohol dehydrogenase purification

The most efficient, specific and rapid procedures for alcohol dehydrogenase (ADH) purification utilize immobilized 4-(3-aminopropyl) pyrazole to which pyrazole sensitive ADHs, i.e. class I isozymes, bind. Because of the length of the reported synthesis of this affinity resin, we synthesized the 4-(3-aminopropyl) pyrazole ligand by a new method in two steps from commercially available nicotinaldehyde. The ligand synthesized by this simplified procedure was directly coupled to the chain-extended support, Activated CH-Sepharose 4B, to yield the same ligand-spacer combination as reported by L.G. Lange and B.L. Vallee (Biochem. 15: 4681-4686, 1976). Human and hamster class I ADHs purified using this resin were homogeneous by SDS-PAGE followed by silver staining. Specific activity and recovery of human class I ADH were comparable to those previously reported.

Acetylcholine receptor alpha-, beta-, gamma-, and delta-subunit mRNA levels are regulated by muscle activity

Denervation of adult skeletal muscle results in increased sensitivity to acetylcholine in extrajunctional regions of the muscle fiber. This increase in acetylcholine sensitivity is accompanied by a large increase in the level of mRNAs coding for the alpha-, beta-, gamma-, and delta-subunits of the acetylcholine receptor. To determine whether muscle activity is sufficient to regulate expression of extrajunctional acetylcholine receptor mRNA levels, denervated muscles were stimulated with extracellular electrodes. Direct stimulation of denervated muscle suppresses both the increase in extrajunctional acetylcholine sensitivity and the expression of mRNA encoding the alpha-, beta-, gamma-, and delta-subunits of the acetylcholine receptor. These results show that muscle activity regulates the level of extrajunctional acetylcholine receptors by regulating the expression of their mRNAs.

Purification and characterization of three forms of class III alcohol dehydrogenase

We have resolved and characterized three forms of human and rat hepatic class III alcohol dehydrogenase. Separations were carried out in narrow immobilized pH gradients. Both in humans and rats the three forms were visualized by enzyme staining with cinnamol, but not with ethanol. They were insensitive to the inhibitory effect of pyrazole. The isoelectric points were approximately from 6.3-6.4, from 5.9-6.0 and 5.6. Each electroeluted enzyme extract, purified further by analytical isoelectric focusing over the pH range from 5-6 or 6-7, revealed a single band by enzyme and silver staining and by Western blotting followed by avidin-biotin staining. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate of each extract revealed a single molecular mass species corresponding to class III alcohol dehydrogenase (ADH). All forms of class III alcohol dehydrogenase were recognized by antisera raised against total class III ADH.

Review of the molecular biology of the human alcohol dehydrogenase genes and gene products

Using protein and enzymatic methods, a major role in ethanol metabolism was assigned to the alcohol dehydrogenase (ADH) enzymes. Three major classes of ADHs were described on the basis of structure and function, including timing and location of expression. Polymorphic variants, including a common functional variant, were identified. Molecular cloning allowed the demonstration of a high degree of sequence homology between the three class I ADH genes and enabled the definition of ADH variants at the DNA sequence level. The existence of an ADH gene cluster on chromosome 4 and the shared evolutionary roots of these genes suggests that the continued integration of studies of the different ADH genes will yield further insights into alcohol metabolism in humans.

Molecular markers for linkage of genetic loci contributing to alcoholism

Specific locus and random locus linkage approaches to identify markers for genes whose allelic variants predispose to alcoholism or for genes controlling relevant physiological and behavioral phenotypes are discussed. Sib-pair analysis is superior for the direct analysis of complex genetic traits such as alcoholism, but classic family analysis will be useful for transmission and linkage analysis for marker traits whose genetics is less complex. In mice, a large number of inbred strains, recombinant inbred and congenic strains, and specifically selected outbred strains are available. In the human, an intriguing linkage result has emerged between a brain protein variant and alcoholism accompanied by suicide. In the mouse, preliminary linkages have been established to loci controlling ethanol preference and also activation after ethanol. Large panels of random DNA and protein genetic probes and of probes for specific loci will in the future increase the probability of establishing linkage in both species.

Functional expression of two neuronal nicotinic acetylcholine receptors from cDNA clones identifies a gene family

A family of genes coding for proteins homologous to the alpha subunit of the muscle nicotinic acetylcholine receptor has been identified in the rat genome. These genes are transcribed in the central and peripheral nervous systems in areas known to contain functional nicotinic receptors. In this paper, we demonstrate that three of these genes, which we call alpha 3, alpha 4, and beta 2, encode proteins that form functional nicotinic acetylcholine receptors when expressed in Xenopus oocytes. Oocytes expressing either alpha 3 or alpha 4 protein in combination with the beta 2 protein produced a strong response to acetylcholine. Oocytes expressing only the alpha 4 protein gave a weak response to acetylcholine. These receptors are activated by acetylcholine and nicotine and are blocked by Bungarus toxin 3.1. They are not blocked by alpha-bungarotoxin, which blocks the muscle nicotinic acetylcholine receptor. Thus, the receptors formed by the alpha 3, alpha 4, and beta 2 subunits are pharmacologically similar to the ganglionic-type neuronal nicotinic acetylcholine receptor. These results indicate that the alpha 3, alpha 4, and beta 2 genes encode functional nicotinic acetylcholine receptor subunits that are expressed in the brain and peripheral nervous system.

Further delineation of the McKusick-Kaufman hydrometrocolpos-polydactyly syndrome

Six cases of the McKusick-Kaufman syndrome (MKS), including two cases that were diagnosed prenatally, were studied. Review of the 54 previously described cases indicates that postaxial polydactyly and hydrometrocolpos in female patients are the hallmark features of this entity. Other manifestations, such as malformations of gastrointestinal, cardiovascular, and ophthalmic structures, occur less consistently. Affected children require careful medical follow-up. Recurrence of hydrometrocolpos following surgical repair may lead to serious sequelae, such as chronic renal failure. We believe that MKS is a distinct panethnic genetic entity, inherited in an autosomal recessive fashion, and that the diagnosis should be made only in female patients with hydrometrocolpos and polydactyly or in male patients with polydactyly who have an affected female relative.

Mapping of a putative genetic locus determining ethanol intake in the mouse

In the mouse, there is evidence that a single genetic locus is a major determinant of differences in ethanol intake between some preferring and non-preferring inbred strains. In this report, we present evidence from two independent experiments indicating that this locus maps to chromosome 1 and that its expressed product is the abundant protein LTW-4 (a 28 kDa, pI 5.6 protein expressed in brain, liver and kidney). The genetic association was found using a panel of 14 polypeptides of mouse brain which were visualized by two-dimensional electrophoresis and which exhibit genetic variation in isoelectric point. Fifteen BXD recombinant inbred strains and the two parental strains were typed for these loci and also tested for ethanol acceptance. Strains exhibiting the basic allele showed significantly higher ethanol acceptance. When 19 distantly related inbred mouse strains were tested for ethanol acceptance and typed for LTW-4, it was again found that strains exhibiting the basic allele showed significantly higher ethanol acceptance.

Genetic variants of C2 muscle cells that are defective in synthesis of the alpha-subunit of the acetylcholine receptor

We have analyzed two genetic variants of C2 muscle cells that have reduced levels of binding activity for alpha-bungarotoxin and have found that both synthesize only low levels of the alpha-subunit of the acetylcholine receptor. In both variants the uptake of 22Na in response to carbachol is diminished in proportion to the reduction in toxin-binding activity. In addition, the kinetic and sedimentation properties of the residual toxin-binding activity in both is indistinguishable from that seen in wild-type cells. Immunoblotting experiments on extracts of the variants using subunit-specific antibodies to alpha- and beta-subunits of the acetylcholine receptor demonstrated that the beta-subunit was present, but failed to detect alpha-subunit. In both variants, the amount of alpha-subunit accumulated after a 5-min period of labeling with [35S]methionine was reduced by over 90%, leading to the conclusion that the alpha-subunit is synthesized at greatly reduced rates. Northern blot and S1 nuclease analysis showed no differences between the alpha-subunit mRNA in wild-type and variant cells.

A molecular phylogeny of the hominoid primates as indicated by two-dimensional protein electrophoresis

A molecular phylogeny for the hominoid primates was constructed by using genetic distances from a survey of 383 radiolabeled fibroblast polypeptides resolved by two-dimensional electrophoresis (2DE). An internally consistent matrix of Nei genetic distances was generated on the basis of variants in electrophoretic position. The derived phylogenetic tree indicated a branching sequence, from oldest to most recent, of cercopithecoids (Macaca fascicularis), gibbon-siamang, orangutan, gorilla, and human-chimpanzee. A cladistic analysis of 240 electrophoretic characters that varied between ape species produced an identical tree. Genetic distance measures obtained by 2DE are largely consistent with those generated by other molecular procedures. In addition, the 2DE data set appears to resolve the human-chimpanzee-gorilla trichotomy in favor of a more recent association of chimpanzees and humans.

Muscle acetylcholine receptor biosynthesis. Regulation by transcript availability

The expression of the muscle nicotinic acetylcholine receptor (AChR) on the cell surface entails a complex biosynthetic pathway, involving the expression and assembly of four subunits. The amount of AChR on the cell surface changes throughout muscle development and upon muscle denervation. We have examined the regulatory role of transcript levels on surface AChR expression by RNA blot analysis. During myogenesis of the fusing mouse muscle cell line C2, which expresses an embryonic type of receptor, changes in the rate of appearance of cell surface AChR have been assayed by 125I-alpha-bungarotoxin binding. The maximal increase in the rate of appearance of cell surface AChR occurs upon cell fusion, closely following the maximal increase in transcript levels for the alpha-, beta-, gamma-, and delta-AChR subunits. AChR alpha-, beta-, gamma-, and delta-subunit gene transcript levels have also been examined in innervated and denervated rat and mouse muscle. Muscle denervation results in an increase of transcripts for all four subunits. However, the amount of beta-subunit transcript in innervated rat skeletal muscle is high relative to the other subunit transcripts, and increases less than the other subunit transcripts upon denervation. Our results indicate that, during myogenesis and upon denervation, the availability of AChR subunit transcripts for translation plays a regulatory role in surface AChR appearance.

Members of a nicotinic acetylcholine receptor gene family are expressed in different regions of the mammalian central nervous system

Nicotinic acetylcholine receptors found in the peripheral and central nervous system differ from those found at the neuromuscular junction. Recently we isolated a cDNA clone encoding the alpha subunit of a neuronal acetylcholine receptor expressed in both the peripheral and central nervous system. In this paper we report the isolation of a cDNA encoding the alpha subunit of a second acetylcholine receptor expressed in the central nervous system. Thus it is clear that there is a family of genes coding for proteins with sequence and structural homology to the alpha subunit of the muscle nicotinic acetylcholine receptor. Members of this gene family are expressed in different regions of the central nervous system and, presumably, code for subtypes of the nicotinic acetylcholine receptor.

Protein polymorphisms detected by two-dimensional electrophoresis: an analysis of overall informativeness of a panel of linkage markers

Forty-two independent polymorphic loci are detectable by two-dimensional electrophoresis (2DE) of four peripherally accessible human tissues. Fifteen have been chromosomally mapped and, taken together, these constitute a useful panel of markers for genetic linkage studies in humans. An analysis of the overall informativeness for linkage of this panel of markers is presented, taking into account the effect of varying the number of families or matings studies. Use of 2DE polymorphic markers for linkage of genetically determined behaviour traits in humans and mice is reviewed.

Nonpyramidal motor activation produced by stimulation of the cerebellum, direct or transcranial: a cerebellar evoked potential

There is a need to monitor the functional status of the motor pathways well enough to predict the state of that function during operations and in injured or diseased patients. We previously reported that a motor evoked potential (MEP) can be produced by direct or transcranial stimulation of the motor cortex in both cats and humans. This signal descends through both the dorsolateral and ventral spinal cord and is primarily localized in the pyramidal tracts, producing a peripheral nerve signal and an electromyogram (EMG) response. It is more sensitive to injury than the somatosensory evoked potential (SEP). We report here that one can stimulate the cerebellar cortex, either directly or transcranially, and produce a descending signal in the spinal cord that has different characteristics from the MEP. The cerebellar evoked potential (CEP), located in the dorsolateral and the ventral cord, has an earlier latency and a faster conduction velocity than the MEP. It is predominantly ipsilateral with some contralateral components and also produces EMG responses. In the peripheral nerves, the CEP often produces a pattern of several waves that is different from the one or two predominant contralateral waves of the MEP. The CEP is not diminished by pyramidotomy. It arises from two sites on the cerebellar cortex, medial and lateral. The pathways activated may be the vestibulospinal, rubrospinal, reticulospinal, and fastigiospinal systems. This test seems to offer a monitor of selected motor pathways in the spinal cord largely separate from and complementary to the MEP. The ventral pathways activated probably include those demonstrated to be most essential to basic ambulation after spinal cord injury in primates. Also of importance, one type of evoked potential can facilitate another, which provides additional diagnostic tests. The CEP should be of investigative and clinical value.

Mapping of brain areas expressing RNA homologous to two different acetylcholine receptor alpha-subunit cDNAs

We have used an in situ RNA X RNA hybridization technique to determine, in the central nervous systems of the mouse and rat, the distribution of RNA homologous to cDNA clones encoding the alpha subunit of a putative neural nicotinic acetylcholine receptor and the alpha subunit of the muscle nicotinic acetylcholine receptor. Hybridization of the neural alpha-subunit probe was strongest in the medial habenula but was also detected consistently in the compact part of the substantia nigra and ventral tegmental area, in the neocortex, and in certain parts of the thalamus and hypothalamus. The in situ hybridization technique makes it possible to compile a map of brain regions containing cell bodies expressing RNA coding for a specific receptor type and subsequently to apply the techniques of molecular biology to study these brain receptors.

Fourteen genetically variant proteins of mouse brain: discovery of two new variants and chromosomal mapping of four loci

With the description here of variant proteins A13 (pI 5.9, MW 62 kd) and A14 (pI 5.3, MW 26 kd), 14 polypeptides of mouse brain visualized by two-dimensional electrophoresis (2DE) exhibit genetic variation in isoelectric point. Using 22 B X D recombinant inbred strains, we map four of these loci and show that a fifth is independent of known loci. A pI 5.6, 81-kd protein of mouse brain mitochondria designated A1 is demonstrated to be an independent locus closely linked to LY-2 and LVP-1 on mouse chromosome 6. A pI 5.6, 28-kd genetically variant brain polypeptide designated A12 maps to chromosome 1 and shows identity with the known mouse locus LTW-4. The locus for A8 is not closely linked to any previously mapped locus. However, the locus for the newly described variant A13 shows 3 of 18 recombinants with the DNA polymorphism RN7S-2 and 2 of 18 recombinants with HC (hemolytic complement) and is thus probably located proximally to HC near the centromere of chromosome 2. Genetic and biochemical evidence is presented for the identification of A14 as ALP-1 (apolipoprotein 1), mapping to chromosome 9. In addition to these 13 genetically variant polypeptides, the positions of 12 other polypeptides which have been identified on 2DE gels of mouse brain are given.

Isolation of a cDNA clone coding for a possible neural nicotinic acetylcholine receptor alpha-subunit

We have isolated a complementary DNA clone containing sequences homologous to those encoding the alpha-subunit of a mouse muscle nicotinic acetylcholine receptor. Based on the structural similarities between the encoded protein and the muscle acetylcholine receptor alpha-subunit, and the presence of hybridizing RNA species in the brain, we propose that this clone codes for a neural nicotinic acetylcholine receptor alpha-subunit.

Use of chromosomally mapped and identified mouse brain proteins for behavioral genetic analysis of alcoholism

A logical first place to look in order to identify loci determining behavioral differences between inbred and certain outbred strains of mice is among the proteins expressed in brain. Fourteen mouse brain proteins have been demonstrated to be genetically variant, four of these have been chromosomally mapped and an additional twelve have been identified and can be simultaneously screened by two dimensional electrophoresis. Certain genetic differences in behavior relevant to alcohol consumption and the effects of alcohol occur between inbred, recombinant inbred and selectively outbred strains. Two genetic correlations are reported, one between an isoelectric point variant of A7 (a 71 kd, pI 5.4 abundant protein) and resistance to signs of ethanol withdrawal and the other between A12 (a 28 kd, pI 5.6 protein) and ethanol intake. Though tentative, these findings illustrate the power of this approach for behavioral genetic analysis and may allow the biochemical genetic bases of these traits to be understood.

Isolation and sequence of cDNA clones coding for the precursor to the gamma subunit of mouse muscle nicotinic acetylcholine receptor

cDNA libraries have been constructed in plasmid (pBR322) and bacteriophage lambda gammagt10) vectors with poly (A+) RNA isolated from the nonfusing mouse muscle cell line BC3H-1. The libraries were screened with a restriction fragment derived from a genomic clone coding for a human acetylcholine receptor gamma subunit. Several clones were obtained whose cDNA inserts possessed nucleotide and deduced amino acid sequence homology with acetylcholine receptor gamma subunits from Torpedo californica, chick, calf, and human. One isolate, lambda BMG419, has 88 nucleotides of 5'-untranslated sequence, an open reading frame of 1,557 nucleotides coding for the precursor to the mouse acetylcholine receptor gamma subunit, and 144 nucleotides of 3'-untranslated sequence. Alignment of the lambda BMG419-deduced amino acid sequence with homologs from other species predicts a precursor peptide of 519 amino acids and a mature protein of 497 amino acids, with nonglycosylated molecular weights of 58,744 and 56,424 daltons, respectively. Comparison of the deduced amino acid sequence of the mouse gamma subunit with Torpedo, chick, calf, and human sequences showed overall homologies of 54%, 67%, 90%, and 90%, respectively; however, significantly higher homologies were found in several putative functional domains. Radiolabeled lambda BMG419 has been used to identify homologous RNA species, one of approximately 2 kb and one of about 3.5 kb, in poly (A+) RNA prepared from BC3H-1 cells and denervated mouse limb muscle. gamma Subunit-coding RNA species are considerably more abundant in denervated than in innervated muscle, suggesting that neural regulation of the abundance of the gamma subunit is exerted through regulation of the amount of its mRNA.

Muscle denervation increases the levels of two mRNAs coding for the acetylcholine receptor alpha-subunit

The mRNA coding for the alpha-subunit of the acetylcholine receptor was studied in mouse leg and rat diaphragm muscle. We find that denervation of rat diaphragm results in a 7-fold increase in mRNA coding for the alpha-subunit, whereas denervation of mouse leg muscle results in approximately a 50-fold increase in alpha-subunit-specific mRNA. The relationship of the mRNAs purified from innervated and denervated muscle was investigated by SI nuclease mapping. Two mRNA species were found in both innervated and denervated muscle which differ in their 3'-untranslated region. The levels of both these mRNA species increase upon denervation of mouse leg muscle.

Twenty-seven protein polymorphisms by two-dimensional electrophoresis of serum, erythrocytes, and fibroblasts in two pedigrees

Twenty-seven independent polymorphic loci were detected by two-dimensional electrophoresis (2DE) of serum, erythrocytes, and fibroblasts in two large families and analyzed for linkage to classical genetic markers. We detected seven serum, four erythrocyte, and 17 fibroblast protein loci that exhibited charge variation in these two families and in a sample of unrelated individuals. The genetic basis of protein variants was confirmed by quantitative gene-dosage dependence and by conformance to Mendelian transmission in the two families, except for four rare variants for which transmission analysis was not possible. Linkage analysis demonstrated that each of the variants represent products of independent loci, with the exception of erythrocyte locus (RBC4), which we also detected in fibroblasts (NC27). Two allozyme polymorphisms, glyoxalase-1 (GLO1) and phosphoglucomutase-3 (PGM3) were specifically identified here based on genotypic concordance and molecular mass. Unknown fibroblast protein (NC22) may be linked to apolipoprotein E (lod score = 2.8 at theta m = theta f = 0), while a serum protein locus (SER1) may be linked to alpha-haptoglobin (lod score = 2.54 at theta m = .20, theta f = .01). Six of seven polymorphic serum loci were previously located on two-dimensional gels: alpha-1 antitrypsin (PI), Gc-globulin (GC), alpha-2 HS glycoprotein (HSGA), alpha-haptoglobin (HP), and two apolipoproteins (APOE and APOA4). Six of 17 polymorphisms detected in fibroblasts were positionally identical to polymorphic loci seen in lymphocytes. These studies indicate a minimum level of average protein charge heterozygosity of approximately 2.2% for the most predominant human cellular proteins and of 5.6% for the most predominant proteins of serum.

Genetic brain polypeptide variants in inbred mice and in mouse strains with high and low sensitivity to alcohol

Twelve genetically determined brain polypeptide charge variants were identified by comparing cerebellar vermis of 7 inbred mouse strains and of mice selectively bred from 8 strains closely related to these 7 ancestral strains and one other for acute behavioral sensitivity to the sedative effects of ethanol. The selectively bred ethanol-sensitive (LS, long sleep) and insensitive (SS, short sleep) mice exhibited different allelic variants at 6 of these 12 gene loci expressed in the cerebellum. Variant polypeptide A1 (81 kdalton, pI 5.6) was shown to be associated with the membrane of synaptosomal mitochondria and to exhibit a basic variant in SS mice that is determined by a dominant allele. Other variant polypeptides showed codominant inheritance in F1 crosses. However, the phenotype of no single one of these brain polypeptides consistently correlated with the ethanol behavioral sensitivity of the 7 inbred mouse strains nor of 8 recombinant inbred (B X D, C57BL X DBA) strains. This finding supports the hypothesis that a substantial amount of inbreeding, leading to random fixation of alleles independent of selection for ethanol sensitivity, occurred during the breeding of the SS and LS mice. The present findings of a lack of a strong association between sleep time and a brain polypeptide variant do not preclude the existence of a major gene effect contributing to variation in acute sensitivity to ethanol but are consistent with reports that multiple loci are responsible for the difference in ethanol sensitivity between SS and LS mice.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of supplemental vitamin A on the healing of colon anastomosis

The effect of dietary supplementation with vitamin A on the healing of colon anastomoses was studied. Fifty adult male Sprague-Dawley rats were divided into two groups: (1) rats fed a standard chow which contains the equivalent of about 15 IU vitamin A/g diet; (2) rats fed the chow supplemented with an additional 150 IU vitamin A/g diet. Rats were prefed for 5 days; on Day 6 under ether anesthesia the colon was divided 1-in. distal to the ileocecal junction and then reanastomosed. The rats were maintained on the above diets for 5 days and killed on the sixth postoperative day with ether and the segment of colon containing the anastomosis was resected. In 15 rats of each group, the breaking strength of the anastomosis was measured. In the remaining 10 rats of each group, the bursting strength of the anastomotic site and a segment of normal distal colon was measured. Samples of colon from the anastomotic site and the normal segment were analyzed for hydroxyproline. There was a significant decrease in hydroxyproline content at the anastomotic site when compared to the normal distal colon segment in each group of rats (P less than 0.01). The hydroxyproline content of both normal colon and the anastomotic site was significantly higher in the vitamin A-supplemented rats than in the control diet rats (P less than 0.01). There was also a significant increase in bursting strength in the vitamin A-supplemented rats both of the anastomotic site (P less than 0.01) and of the normal colon segment (P less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)

Mapping and quantitation of proteins from discrete nuclei and other areas of the rat brain by two-dimensional gel electrophoresis

A map of the location and relative concentration of a number of different proteins present in 25 distinct neuroanatomical regions of the male rat brain has been established utilizing two-dimensional polyacrylamide gel electrophoresis. The regions examined include cortical areas as well as nuclei from the hypothalamus, amygdala, thalamus, forebrain, and hindbrain. Tissue samples were obtained from each region of interest by microdissection. Proteins within these samples were first separated by charge using the technique of isoelectric focusing. In the second dimension, proteins were separated by mass on polyacrylamide slab gels containing sodium dodecyl sulfate. Proteins were visualized using a highly sensitive silver stain and quantitated by computerized scanning densitometry. The results demonstrate that all proteins examined varied somewhat in concentration among the different brain regions. The majority (53%) of polypeptides selected for quantitation were found to vary less than 4-fold in concentration between the neuroanatomical areas with the lowest and highest detected amounts. In contrast, approximately 10% of the proteins examined varied widely in the quantity measured in each brain region, with concentration values ranging more than 10-fold between the regions with the lowest and highest detected amounts. This atlas is a first attempt at systematically classifying the mass, charge, and relative concentration of proteins present in a variety of regions of the rat brain. The system presented here will serve as a basis for future studies in this area.

Sensation seeking, augmenting-reducing, and absolute auditory threshold: a strength-of-the-nervous-system perspective

The following measures were obtained from 42 student volunteers: the General and the Disinhibition subscales of the Sensation Seeking Scale (Form IV), the Reducer-Augmenter Scale, and the Absolute Auditory Threshold. General sensation seeking correlated significantly with the Reducer-Augmenter Scale, r(40) = .59, p less than .001, and the Absolute Auditory Threshold, r(40) = .45, p less than .005. Both results proved general across sex. These findings, that high-sensation seekers tend to be reducers and to lack sensitivity to weak stimulation, were interpreted as supporting strength-of-the-nervous-system theory more than the formulation of Zuckerman and his associates.

Protein variations associated with in vitro aging of human fibroblasts and quantitative limits on the error catastrophe hypothesis

Two-dimensional electrophoresis was used to examine protein alterations associated with in vitro cellular aging. Patterns of cellular proteins from early and late passage human fibroblasts of two strains (normal and trisomy 21) were analyzed in silver-stained gels and autoradiograms with computerized microdensitometry. Four proteins were significantly altered in density in both cell strains. In late passage cells, these proteins were from 6 to 66% the density in early passage cells. The error catastrophe hypothesis predicts that random amino acid substitutions accumulate with cellular aging. No new proteins or satellite spots due to such substitutions, however, were detected in late passage cells. An upper bound of 2.5% was set by high resolution densitometry for the fraction of abnormal protein that could be present but undetected by these methods.

Human lymphocyte polymorphisms detected by quantitative two-dimensional electrophoresis

A survey of 186 soluble lymphocyte proteins for genetic polymorphism was carried out utilizing two-dimensional electrophoresis of 14C-labeled phytohemagglutinin (PHA)-stimulated human lymphocyte proteins. Nineteen of these proteins exhibited positional variation consistent with independent genetic polymorphism in a primary sample of 28 individuals. Each of these polymorphisms was characterized by quantitative gene-dosage dependence insofar as the heterozygous phenotype expressed approximately 50% of each allelic gene product as was seen in homozygotes. Patterns observed were also identical in monozygotic twins, replicate samples, and replicate gels. The three expected phenotypes (two homozygotes and a heterozygote) were observed in each of 10 of these polymorphisms while the remaining nine had one of the homozygous classes absent. The presence of the three phenotypes, the demonstration of gene-dosage dependence, and our own and previous pedigree analysis of certain of these polymorphisms supports the genetic basis of these variants. Based on this data, the frequency of polymorphic loci for man is: P = 19/186 = .102, and the average heterozygosity is .024. This estimate is approximately 1/3 to 1/2 the rate of polymorphism previously estimated for man in other studies using one-dimensional electrophoresis of isozyme loci. The newly described polymorphisms and others which should be detectable in larger protein surveys with two-dimensional electrophoresis hold promise as genetic markers of the human genome for use in gene mapping and pedigree analyses.

Sensation seeking, augmenting-reducing, and absolute auditory threshold: a strength-of-the-nervous-system perspective

The following measures were obtained from 42 student volunteers: the General and the Disinhibition subscales of the Sensation Seeking Scale (Form IV), the Reducer-Augmenter Scale, and the Absolute Auditory Threshold. General sensation seeking correlated significantly with the Reducer-Augmenter Scale, r(40) = .59, p less than .001, and the Absolute Auditory Threshold, r(40) = .45, p less than .005. Both results proved general across sex. These findings, that high-sensation seekers tend to be reducers and to lack sensitivity to weak stimulation, were interpreted as supporting strength-of-the-nervous-system theory more than the formulation of Zuckerman and his associates.

The Cheetah Is Depauperate in Genetic Variation

A sample of 55 South African cheetahs (Acinonyx jubatus jubatus) from two geographically isolated populations in South Africa were found to be genetically monomorphic at each of 47 allozyme (allelic isozyme) loci. Two-dimensional gel electrophoresis of 155 abundant soluble proteins from cheetah fibroblasts also revealed a low frequency of polymorphism (average heterozygosity, 0.013). Both estimates are dramatically lower than levels of variation reported in other cats and mammals in general. The extreme monomorphism may be a consequence of a demographic contraction of the cheetah (a population bottleneck) in association with a reduced rate of increase in the recent natural history of this endangered species.

Clinical research in neuropsychiatry

This paper presents the thesis that rapidly developing areas of knowledge in neuroscience will rekindle interest in neuropsychiatry, and increase scientific and clinical interaction between psychiatrists and neurologists in teaching hospitals. A neuropsychiatric clinical research unit at the National Institute of Mental Health is described. Examples of research conducted on the unit illustrate areas of biological science that are likely to increase the interface between psychiatry and neurology. Hopefully, the explosion of knowledge in the basic neurosciences in the last decade will be followed in this decade by clinical research of increasing specificity and sophistication of central nervous system disorders.

Maternal transmission in Huntington's disease

The effect of maternal transmission on age at onset of Huntington's disease (HD) was examined in 100 unrelated pedigrees. The age at which abnormal movement disorder first appeared could be estimated in 238 patients. More than twice as many of the late-onset cases (age 50 or later) inherited the HD gene from an affected mother than from an affected father. Affected offspring of late-onset females also had late-onset disease while those of late-onset males had significantly earlier ages of onset. This pattern of maternal inheritance suggests a model where the late-onset form of HD is related to a maternally transmitted factor such as the mitochondrion and its genome.

Quantitative two-dimensional protein electrophoresis for studies of inborn errors of metabolism

High-resolution electrophoretic methods and sensitive protein-detection techniques permit new approaches to understanding and diagnosis of the inborn errors of metabolism. These approaches encompass: the search for protein alterations that represent primary mutations effects; observation of alterations in protein patterns due to secondary effects, as might occur in major metabolic pathway abnormalities; and identification of protein polymorphisms that are genetically linked to an inborn metabolic disease. With the aid of computer analysis of the electrophoretograms, all three approaches are being developed. Protein density and position are evaluated with an interactive computer program that requires that gel polypeptides be indexed by the investigator. Proteins on the gels are made visible with an inexpensive, rapid silver stain, which can be used quantitatively. The Lesch-Nyhan syndrome, one of a few neuropsychiatric diseases for which the molecular defect is known, was chosen for study with these techniques. Four hundred proteins were analyzed for positional or quantitative variation. Eleven significant (2p less than 0.01) quantitative differences were found in autoradiograms from gels of phytohemagglutinin-stimulated lymphocytes. Specific patterns of polypeptide variation are now being sought in an expanded clinical study primarily focusing on Huntington's disease. Large studies are required to establish the specificity of observed alterations. As the number and variety of analyses increase, a correlative catalog of molecular variation and polymorphism will be generated.

Lymphocyte proteins in Huntington's disease: quantitative analysis by use of two-dimensional electrophoresis and computerized densitometry

We used quantitative two-dimensional electrophoresis to study lymphocyte proteins in Hungtington's disease. Three hundred and six polypeptides from 14C-labeled, phytohemagglutinin-stimulated lymphocytes were measured for variation in relative spot density and 186 for variation in spot position by use of a computer program requiring operator interaction. Each polypeptide was measured in a total of 30 electrophoretograms from 28 individuals, including 13 with Huntington's disease, 2 at risk for it, and 13 controls. The study included two sets of identical twins and, as neurological controls, individuals with neurofibromatosis, Alzheimer's disease, or Shy-Drager syndrome. Seven protein polymorphisms were identified among the 186 most dense polypeptides of each gel, corresponding to a minimum average heterozygosity of 1.4%. Stringent criteria were used to define polymorphic proteins, including observation of at least one individual with each of two homozygous phenotypes and one with the heterozygous phenotype, demonstration of the expected gene dosage relationship by quantitative densitometry, consistency with genetic relationships, and reproducibility. One polymorphic protein showed three electrophoretically variant alleles. Our identification of seven polymorphisms among the 186 proteins measured on a single electrophoretogram illustrates the potential of this technique for performing linkage analysis in diseases of genetic origin. However, we observed no quantitative or positional protein variations that were characteristic of (i.e. specific for) Huntington's disease.

Lymphocyte proteins in Huntington's disease: quantitative analysis by use of two-dimensional electrophoresis and computerized densitometry

We used quantitative two-dimensional electrophoresis to study lymphocyte proteins in Hungtington's disease. Three hundred and six polypeptides from 14C-labeled, phytohemagglutinin-stimulated lymphocytes were measured for variation in relative spot density and 186 for variation in spot position by use of a computer program requiring operator interaction. Each polypeptide was measured in a total of 30 electrophoretograms from 28 individuals, including 13 with Huntington's disease, 2 at risk for it, and 13 controls. The study included two sets of identical twins and, as neurological controls, individuals with neurofibromatosis, Alzheimer's disease, or Shy-Drager syndrome. Seven protein polymorphisms were identified among the 186 most dense polypeptides of each gel, corresponding to a minimum average heterozygosity of 1.4%. Stringent criteria were used to define polymorphic proteins, including observation of at least one individual with each of two homozygous phenotypes and one with the heterozygous phenotype, demonstration of the expected gene dosage relationship by quantitative densitometry, consistency with genetic relationships, and reproducibility. One polymorphic protein showed three electrophoretically variant alleles. Our identification of seven polymorphisms among the 186 proteins measured on a single electrophoretogram illustrates the potential of this technique for performing linkage analysis in diseases of genetic origin. However, we observed no quantitative or positional protein variations that were characteristic of (i.e. specific for) Huntington's disease.

Quantitative two-dimensional protein electrophoresis for studies of inborn errors of metabolism

High-resolution electrophoretic methods and sensitive protein-detection techniques permit new approaches to understanding and diagnosis of the inborn errors of metabolism. These approaches encompass: the search for protein alterations that represent primary mutations effects; observation of alterations in protein patterns due to secondary effects, as might occur in major metabolic pathway abnormalities; and identification of protein polymorphisms that are genetically linked to an inborn metabolic disease. With the aid of computer analysis of the electrophoretograms, all three approaches are being developed. Protein density and position are evaluated with an interactive computer program that requires that gel polypeptides be indexed by the investigator. Proteins on the gels are made visible with an inexpensive, rapid silver stain, which can be used quantitatively. The Lesch-Nyhan syndrome, one of a few neuropsychiatric diseases for which the molecular defect is known, was chosen for study with these techniques. Four hundred proteins were analyzed for positional or quantitative variation. Eleven significant (2p less than 0.01) quantitative differences were found in autoradiograms from gels of phytohemagglutinin-stimulated lymphocytes. Specific patterns of polypeptide variation are now being sought in an expanded clinical study primarily focusing on Huntington's disease. Large studies are required to establish the specificity of observed alterations. As the number and variety of analyses increase, a correlative catalog of molecular variation and polymorphism will be generated.