Your search keyword '"Thomas H. Roderick"' showing total 98 results

1. Inference of Order in Genetic Systems.

Author

John N. Guidi and Thomas H. Roderick

Published

1993

2. Identification of an HMGB3 Frameshift Mutation in a Family With an X-linked Colobomatous Microphthalmia Syndrome Using Whole-Genome and X-Exome Sequencing

Author

Raquel Pittiglio, Beth A. Marosy, Ethylin Wang Jabs, P Calvas, Nicolas Chassaing, Roxann G. Ingersoll, Jill A. Barton, Alan F. Scott, David W. Mohr, Shreya S. Prabhu, Thomas H. Roderick, William C. Bromley, Brian Craig, Laura Kasch, Kimberly F. Doheny, Johns Hopkins University School of Medicine [Baltimore], The Jackson Laboratory [Bar Harbor] (JAX), Unité différenciation épidermique et auto-immunité rhumatoïde (UDEAR), Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Institut National de la Santé et de la Recherche Médicale (INSERM), CHU Toulouse [Toulouse], and Icahn School of Medicine at Mount Sinai [New York] (MSSM)

Subjects

Proband, Male, MESH: Microcephaly / genetics, Candidate gene, MESH: Sequence Analysis, DNA, MESH: Chromosomes, Human, X / genetics, MESH: HMGB3 Protein / genetics, MESH: Pedigree, MESH: Frameshift Mutation / genetics, MESH: Exome / genetics, Biology, Polymerase Chain Reaction, DNA sequencing, MESH: Genome, Human / genetics, Frameshift mutation, symbols.namesake, [SDV.MHEP.MI]Life Sciences [q-bio]/Human health and pathology/Infectious diseases, HMGB3 Protein, Intellectual Disability, MESH: Child, Humans, Microphthalmos, Exome, Child, Frameshift Mutation, Exome sequencing, X-linked recessive inheritance, Growth Disorders, Genetics, Sanger sequencing, Chromosomes, Human, X, MESH: Growth Disorders / genetics, MESH: Humans, Genome, Human, Genetic Diseases, X-Linked, MESH: Polymerase Chain Reaction, Sequence Analysis, DNA, MESH: Microphthalmos / genetics, MESH: Male, 3. Good health, Pedigree, Coloboma, MESH: Coloboma / genetics, Ophthalmology, symbols, Microcephaly, MESH: Genetic Diseases, X-Linked / genetics, MESH: Intellectual Disability / genetics

Abstract

International audience; Importance: Microphthalmias are rare disorders whose genetic bases are not fully understood. HMGB3 is a new candidate gene for X-linked forms of this disease.Objective: To identify the causative gene in a pedigree with an X-linked colobomatous microphthalmos phenotype. Design, setting, and participants: Whole-genome sequencing and chromosome X-exome-targeted sequencing were performed at the High Throughput Sequencing Laboratory of the Genetic Resources Core Facility at the Johns Hopkins University School of Medicine on the DNA of the male proband and informatically filtered to identify rare variants. Polymerase chain reaction and Sanger sequencing were used to confirm the variant in the proband and the carrier status of his mother. Thirteen unrelated male patients with a similar phenotype were also screened. Main outcomes and measures: Whole-genome and X-exome sequencing to identify a frameshift variant in HMGB3. Results: A 2-base pair frameshift insertion (c.477_478insTA, coding for p.Lys161Ilefs*54) in the HGMB3 gene was found in the proband and his carrier mother but not in the unrelated patients. The mutation, confirmed by 3 orthogonal methods, alters an evolutionarily conserved region of the HMGB3 protein from a negatively charged polyglutamic acid tract to a positively charged arginine-rich motif that is likely to interfere with normal protein function. Conclusions and relevance: In this family, microphthalmia, microcephaly, intellectual disability, and short stature are associated with a mutation on the X chromosome in the HMGB3 gene. HMGB3 should be considered when performing genetic studies of patients with similar phenotype

Published

2014

3. Mouse paracentric inversion In(3)55Rk mutates the urate oxidase gene

Author

Christopher J. Calvano, James Mandell, Susan A. Cook, Norman L. Hawes, Kenneth R. Johnson, Thomas H. Roderick, Muriel T. Davisson, Roderick T. Bronson, and Ellen C. Akeson

Subjects

Male, Urate Oxidase, DNA Mutational Analysis, Biology, Mice, Gene mapping, Genetics, Animals, RNA, Messenger, Allele, Molecular Biology, Alleles, Crosses, Genetic, In Situ Hybridization, Fluorescence, Genetics (clinical), Chromosomal inversion, Breakpoint, Chromosome Mapping, Urate oxidase, Karyotype, Exons, Null allele, Molecular biology, Mice, Mutant Strains, Chromosome Banding, Uric Acid, Blotting, Southern, Chromosome 3, Chromosome Inversion, Mutation, Female, Kidney Diseases, Polymorphism, Restriction Fragment Length

Abstract

The paracentric inversion In(3)55Rk on mouse Chromosome 3 (Chr 3) was induced by cesium irradiation. Genetic crosses indicate the proximal breakpoint cosegregates with D3Mit324 and D3Mit92; the distal breakpoint cosegregates with D3Mit127, D3Mit160, and D3Mit200. Giemsa-banded chromosomes show the inversion spans ∼80% of Chr 3. The proximal breakpoint occurs within band 3A2, not 3B as reported previously; the distal breakpoint occurs within band 3H3. Mice homozygous for the inversion exhibit nephropathy indicative of uricase deficiency. Southern blot analyses of urate oxidase, Uox, show two RFLPs of genomic mutant DNA: an EcoRI site between exons 4–8 and a BamHI site 3′ to exon 6. Mutant cDNA fails to amplify downstream of base 844 at the 3′ end of exon 7. FISH analysis of chromosomes from inversion heterozygotes, using a cosmid clone containing genomic wild-type DNA for Uox exons 2–4, shows that a 5′ segment of the mutated Uox allele on the inverted chromosome has been transposed from the distal breakpoint region to the proximal breakpoint region. Clinical, histopathological, and Northern analyses indicate that our radiation-induced mutation, uoxIn, is a putative null.

Published

2001

4. A deletion in a photoreceptor-specific nuclear receptor mRNA causes retinal degeneration in the rd7 mouse

Author

A. Rapoport, Steven Nusinowitz, Natik I. Piriev, Muriel T. Davisson, John R. Heckenlively, Christine A. Kozak, Patsy M. Nishina, Norman L. Hawes, Debora B. Farber, Bo Chang, Michael Danciger, Thomas H. Roderick, and N. B. Akhmedov

Subjects

Genetic Markers, Retinal degeneration, Retinal Disorder, Molecular Sequence Data, Receptors, Cytoplasmic and Nuclear, Mice, Inbred Strains, Biology, Frameshift mutation, Mice, chemistry.chemical_compound, Electroretinography, medicine, Animals, Humans, Coding region, Amino Acid Sequence, RNA, Messenger, DNA Primers, Sequence Deletion, Messenger RNA, Multidisciplinary, Base Sequence, Reverse Transcriptase Polymerase Chain Reaction, Retinal Degeneration, Chromosome Mapping, Retinal, Biological Sciences, Orphan Nuclear Receptors, medicine.disease, Molecular biology, Mice, Mutant Strains, Mice, Inbred C57BL, chemistry, Suppression subtractive hybridization, Codon, Terminator, Retinal dysplasia, Photoreceptor Cells, Vertebrate, Transcription Factors

Abstract

The rd7 mouse, an animal model for hereditary retinal degeneration, has some characteristics similar to human flecked retinal disorders. Here we report the identification of a deletion in a photoreceptor-specific nuclear receptor (mPNR) mRNA that is responsible for hereditary retinal dysplasia and degeneration in the rd7 mouse. mPNR was isolated from a pool of photoreceptor-specific cDNAs originally created by subtractive hybridization of mRNAs from normal and photoreceptorless rd mouse retinas. Localization of the gene corresponding to mPNR to mouse Chr 9 near the rd7 locus made it a candidate for the site of the rd7 mutation. Northern analysis of total RNA isolated from rd7 mouse retinas revealed no detectable signal after hybridization with the mPNR cDNA probe. However, with reverse transcription–PCR, we were able to amplify different fragments of mPNR from rd7 retinal RNA and to sequence them directly. We found a 380-nt deletion in the coding region of the rd7 mPNR message that creates a frame shift and produces a premature stop codon. This deletion accounts for more than 32% of the normal protein and eliminates a portion of the DNA-binding domain. In addition, it may result in the rapid degradation of the rd7 mPNR message by the nonsense-mediated decay pathway, preventing the synthesis of the corresponding protein. Our findings demonstrate that mPNR expression is critical for the normal development and function of the photoreceptor cells.

Published

2000

5. Lop12, a Mutation in Mouse Crygd Causing Lens Opacity Similar to Human Coppock Cataract

Author

Xin Wang, John R. Heckenlively, Richard S. Smith, Norman L. Hawes, Muriel T. Davisson, Bo Chang, Ellen C. Akeson, Xiaohua Gong, and Thomas H. Roderick

Subjects

Male, Protein Folding, Candidate gene, DNA, Complementary, Genetic Linkage, DNA Mutational Analysis, Biology, Cataract, Homology (biology), Gene product, Mice, Exon, Species Specificity, Gene mapping, Gene cluster, Genetics, Animals, Humans, Crosses, Genetic, Terminator Regions, Genetic, Mice, Inbred BALB C, Chromosome Mapping, Crystallins, eye diseases, Stop codon, Disease Models, Animal, Female, Protein folding

Abstract

A new cataract mutation was discovered in an ongoing program to identify new mouse models of hereditary eye disease. Lens opacity 12 (Lop12) is a semidominant mutation that results in an irregular nuclear lens opacity similar to the human Coppock cataract. Lop12 is associated with a small nonrecombining segment that maps to mouse Chromosome 1 close to the eye lens obsolescence mutation (Cryge(Cat2-Elo)), a member of the gamma-crystallin gene cluster (Cryg). Using a systemic candidate gene approach to analyze the entire Cryg cluster, a G to A transition was found in exon 3 of Crygd associated with the Lop12 mutation and has been designated Crygd(Lop12). The mutation Crygd(Lop12) leads to the formation of an in-frame stop codon that produces a truncated protein of 156 amino acids. It is predicted that the defective gene product alters protein folding of the gamma-crystallin(s) and results in lens opacity.

Published

2000

6. [Untitled]

Author

Kevin Flurkey, Thomas H. Roderick, J. Chen, M.C. Astle, Jonathan R. Archer, David E. Harrison, and Simon Klebanov

Subjects

Genetics, Offspring, media_common.quotation_subject, Longevity, Plant Science, General Medicine, Heritability, Biology, Regression, Inbred strain, Insect Science, Midparent, Animal Science and Zoology, Maximum life span, Selection (genetic algorithm), media_common, Demography

Abstract

We found high narrow-sense heritability of life span based on the regression of offspring on average parental (midparent) life spans. In two mouse populations prepared using the 4-way-cross design, mean ± SE heritabilities were 62 ± 11% (P ≤ 0.001) and 44 ± 15% (P ≤ 0.01). To reflect inherited rates of aging, rather than resistance to early disease, data from the first 25% to die were deleted, so that only about 40% of families were used for offspring-midparent regressions. Heritabilities still remained high, 38% and 55%, for the same two populations, respectively. Populations studied in two other experiments did not show nearly as high heritabilities; in one case probably due to environmental stress, and in the other probably because the strains used did not have sufficient additive variance in genes regulating longevity. Significant heritabilities occurred only when a wild derived inbred strain was included in the 4-way cross. The age when a female ceased to reproduce appeared to be related to the life spans of her offspring, but only weakly, not approaching significance for any individual experiment. The age when a female became infertile was related to her life span, but the relationship disappeared when short-lived mice were excluded from the analysis. Our findings indicate that, in sufficiently diverse mouse populations, selection for increased longevity should be possible and that the direct selection for parental life span will be a more efficient strategy than selection for female reproductive life span.

Published

2000

7. A New Dominant Retinal Degeneration (Rd4) Associated with a Chromosomal Inversion in the Mouse

Author

John R. Heckenlively, Norman L. Hawes, Bo Chang, and Thomas H. Roderick

Subjects

Male, Retinal degeneration, Locus (genetics), Biology, Mice, chemistry.chemical_compound, Atrophy, Electroretinography, Genetics, medicine, Animals, Humans, Genes, Dominant, Chromosomal inversion, Retina, medicine.diagnostic_test, Retinal Degeneration, Retinal, Anatomy, medicine.disease, Molecular biology, Mice, Inbred C57BL, medicine.anatomical_structure, Chromosome 4, chemistry, Mice, Inbred DBA, Chromosome Inversion, Female, sense organs

Abstract

An autosomal dominant retinal degeneration, called Rd4, was found in a stock carrying the inversion In(4)56Rk, which was induced in a DBA/2J male. The inversion encompasses nearly all of Chromosome 4. It is homozygous lethal and in heterozygotes is always associated with retinal degeneration. In affected mice, the retinal outer nuclear and plexiform layers begin to reduce at 10 days of age, showing total loss at 6 weeks. The recordable electroretinograms (ERG) showed poorly at 3 to 6 weeks and were barely detected after 6 weeks of age. Retinal vessel attenuation, pigment spots, and optic atrophy appeared in the fundus at 4 weeks of age. Rd4 has not recombined with the inversion in an outcross, suggesting that the Rd4 locus is located very close to or is disrupted by one of the breakpoints of the inversion, either near the centromere or near the telomere. A human homolog would be expected to be located on human chromosomes 1p or 8q.

Published

1997

8. Mouse model for Usher syndrome: linkage mapping suggests homology to Usher type I reported at human chromosome 11p15

Author

Gregory S. Hageman, Norman L. Hawes, Thomas H. Roderick, Lawrence C. Erway, Chen Peng, Bo Chang, and John R. Heckenlively

Subjects

Retinal degeneration, Usher syndrome, Genes, Recessive, Deafness, Tubby protein, Biology, Congenital hearing loss, Mice, Genetic linkage, Retinitis pigmentosa, otorhinolaryngologic diseases, medicine, Animals, Humans, Genetics, Chromosome 7 (human), Multidisciplinary, Chromosomes, Human, Pair 11, Retinal Degeneration, Chromosome, Syndrome, Rod Cell Outer Segment, medicine.disease, Mice, Mutant Strains, eye diseases, Mice, Inbred C57BL, Disease Models, Animal, Ear, Inner, Research Article

Abstract

Usher syndrome is a group of diseases with autosomal recessive inheritance, congenital hearing loss, and the development of retinitis pigmentosa, a progressive retinal degeneration characterized by night blindness and visual field loss over several decades. The causes of Usher syndrome are unknown and no animal models have been available for study. Four human gene sites have been reported, suggesting at least four separate forms of Usher syndrome. We report a mouse model of type I Usher syndrome, rd5, whose linkage on mouse chromosome 7 to Hbb and tub has homology to human Usher I reported on human chromosome 11p15. The electroretinogram in homozygous rd5/rd5 mouse is never normal with reduced amplitudes that extinguish by 6 months. Auditory-evoked response testing demonstrates increased hearing thresholds more than control at 3 weeks of about 30 decibels (dB) that worsen to about 45 dB by 6 months.

Published

1995

9. Genetic linkage analysis of the murine developmental mutant velvet coat (Ve) and the distal chromosome 15 developmental genesHox-3.1, Rar-g, Wnt-1, andKrt-2

Author

Kenneth P. LeClair, Charles P. Hart, Frank H. Ruddle, Thomas H. Roderick, A. Zelent, Lisa Hunihan, John G. Compton, and Stephen H. Langley

Subjects

Male, Genetic Linkage, Receptors, Retinoic Acid, Mus spretus, Wnt1 Protein, Mice, Chromosome 15, Gene mapping, Genetic linkage, Proto-Oncogene Proteins, Animals, Genes, Developmental, Allele, Hox gene, Gene, Crosses, Genetic, Homeodomain Proteins, Genetics, Mice, Inbred BALB C, biology, Genes, Homeobox, Chromosome Mapping, General Medicine, Zebrafish Proteins, biology.organism_classification, Molecular biology, DNA-Binding Proteins, Wnt Proteins, Genes, Mutation, embryonic structures, Keratins, Female, Animal Science and Zoology, Restriction fragment length polymorphism, Carrier Proteins, Polymorphism, Restriction Fragment Length, Hair

Abstract

We have identified restriction fragment length polymorphisms between Mus musculus and Mus spretus for the Chromosome 15 loci Hox-3, Wnt-1, Krt-2, Rar-g, and Ly-6. We followed the inheritance of these alleles in interspecific genetic test crosses between velvet coat (Ve) heterozygotes and M. spretus. The results suggest a gene order and recombination distances (in cM) of Ly-6-22-Wnt-1-2-Ve/Krt-2/Rar-g-3-Hox-3. No recombination was found between Ve, Krt-2, and Rar-g. The data also provide evidence for the hypothesis of a large-scale genomic duplication involving homologous gene pairs on mouse Chromosomes 15 and 11.

Published

1992

10. Mouse chromosome 1

Author

Michael F. Seldin, Thomas H. Roderick, and Beverly Paigen

Subjects

Genetics

Published

1991

11. The analysis of recessive lethal mutations in mice by using two-dimensional gel electrophoresis of liver proteins

Author

Norman L. Hawes, John Taylor, M. Anne Gemmell, Sandra L. Tollaksen, Carol S. Giometti, and Thomas H. Roderick

Subjects

Genetic Markers, Male, Heterozygote, Triethylene Melamine, Genes, Recessive, Biology, Toxicology, Protein expression, Mice, Genetics, Animals, Electrophoresis, Gel, Two-Dimensional, Heritable mutation, Gel electrophoresis, Two-dimensional gel electrophoresis, Structural gene, Proteins, A protein, Molecular biology, Isoenzymes, Mice, Inbred C57BL, Liver, Chromosome Inversion, Mutation, Female, Protein abundance

Abstract

We have used two-dimensional gel electrophoresis (2DE) coupled with computer-assisted data analysis to analyze liver-protein expression in mice known to be heterozygous carriers of recessive lethal mutations induced in In(1)1Rk or In(7)13Rk inversion stocks by exposure to either triethylene melamine or ionizing radiation. Carriers of 8 different mutations and corresponding littermate controls (average of 17 individuals in each group) were screened for liver-protein differences. Both qualitative and quantitative protein differences were detected that correlated with unique pedigrees among the mouse stocks analyzed. Such strain-specific differences demonstrated that quantitative differences (either increases or decreases) in protein abundance of greater than 25% can be readily detected by using this 2DE system. Thus the 50% reduction in expression of a protein expected in the event of a structural gene deletion is well within the level of detection. No significant quantitative decreases in protein expression that correlated with the recessive lethal mutations were detected, however.

Published

1990

12. Foreword for Volume I

Author

Thomas H. Roderick

Subjects

Materials science, Volume (thermodynamics), business.industry, Nuclear medicine, business

Published

2007

13. Maximum life spans in mice are extended by wild strain alleles

Author

Kevin Flurkey, Thomas H. Roderick, Clinton M. Astle, David E. Harrison, Jonathan R. Archer, Jichun Chen, and Simon Klebanov

Subjects

0106 biological sciences, 0301 basic medicine, Genetics, Strain (chemistry), Life span, Longevity, Quantitative trait locus, Biology, 010603 evolutionary biology, 01 natural sciences, Survival Analysis, General Biochemistry, Genetics and Molecular Biology, Wild strain, 03 medical and health sciences, Mice, 030104 developmental biology, Animals, Allele, Gene, Alleles, Crosses, Genetic

Abstract

The genes that control basic aging mechanisms in mammals are unknown. By using two four-way crosses, each including a strain derived from wild, undomesticated stocks, we identified two quantitative trait loci that extend murine life spans by approximately 10%. In one cross, the longest-lived 18% of carriers of the D8MH171 marker allele from the MOLD/Rk strain, Mus m. molossinus, outlived the longest lived 18% of noncarriers by 129 days (P = 5.4 × 10–5); in a second cross, carriers of the D10Mit267 allele from the CAST/El strain, Mus m. castaneus, outlived noncarriers by 125 days (P = 1.6 × 10–6). In both crosses, P < 1.0 × 10–4 is considered significant. Because these life span increases required that all essential biological systems function longer than normal, these alleles most likely retarded basic aging mechanisms in multiple biological systems simultaneously.

Published

2001

14. Interacting loci cause severe iris atrophy and glaucoma in DBA/2J mice

Author

Norman L. Hawes, Adriana Zabaleta, Bo Chang, Thomas H. Roderick, Richard S. Smith, Muriel T. Davisson, John R. Heckenlively, Simon W. M. John, Olga V. Savinova, and Michael G. Anderson

Subjects

Pathology, medicine.medical_specialty, Iris pigment dispersion, Iris atrophy, Glaucoma, Iris, Locus (genetics), Mice, Inbred Strains, Biology, Mice, Atrophy, Species Specificity, Genetics, medicine, Animals, Allele, Pigment Epithelium of Eye, Crosses, Genetic, Mice, Inbred BALB C, Membrane Glycoproteins, Homozygote, Age Factors, Chromosome Mapping, Proteins, medicine.disease, Mice, Inbred C57BL, Chromosome 4, Iris Diseases, Mice, Inbred DBA, Pigment dispersion syndrome, sense organs, Oxidoreductases, Microsatellite Repeats

Abstract

Glaucomas are a major cause of blindness. Visual loss typically involves retinal ganglion cell death and optic nerve atrophy subsequent to a pathologic elevation of intraocular pressure (IOP). Some human glaucomas are associated with anterior segment abnormalities such as pigment dispersion syndrome (PDS) and iris atrophy with associated synechiae. The primary causes of these abnormalities are unknown, and their aetiology is poorly understood. We recently characterized a mouse strain (DBA/2J) that develops glaucoma subsequent to anterior segment changes including pigment dispersion and iris atrophy. Using crosses between mouse strains DBA/2J (D2) and C57BL/6J (B6), we now show there are two chromosomal regions that contribute to the anterior segment changes and glaucoma. Progeny homozygous for the D2 allele of one locus on chromosome 6 (called ipd) develop an iris pigment dispersion phenotype similar to human PDS. ipd resides on a region of mouse chromosome 6 with conserved synteny to a region of human chromosome 7q that is associated with human PDS. Progeny homozygous for the D2 allele of a different locus on chromosome 4 (called isa) develop an iris stromal atrophy phenotype (ISA). The Tyrpl gene is a candidate for isa and likely causes ISA via a mechanism involving pigment production. Progeny homozygous for the D2 alleles of both ipd and isa develop an earlier onset and more severe disease involving pigment dispersion and iris stromal atrophy.

Published

1999

15. Medical Genetics: 1984. May 10-12, 1984, in Washington, DC

Author

Victor A. McKusick and Thomas H. Roderick

Subjects

medicine.medical_specialty, business.industry, Family medicine, Genetics, medicine, Medical genetics, business, Genetics (clinical)

Published

2008

16. Selection for maximum longevity in mice

Author

Thomas H. Roderick and David E. Harrison

Subjects

Genetic Markers, Aging, media_common.quotation_subject, Longevity, Mice, Inbred Strains, Biology, Biochemistry, Mice, Endocrinology, Inbred strain, Genetics, Animals, Humans, Allele, Selection, Genetic, Molecular Biology, Gene, Selection (genetic algorithm), media_common, Genetic diversity, Models, Genetic, Mechanism (biology), Reproduction, Genetic Variation, Cell Biology, Genetic marker

Abstract

In both mice and men, during the adult life span, aging causes an exponential increase in vulnerability to almost all pathologies. Thus, aging is a serious public health problem. Altering the basic mechanisms that control normal aging would be a powerful approach to reduce damage from aging processes, so research identifying these mechanisms is of vital importance. Because life spans are determined by the first biological system to malfunction, it is likely that basic mechanisms are involved in life span extension of animals already having maximum normal life spans for the species. When life spans of a species are extended, all biological systems must function for unusually long times. If there area limited number of genes for basic mechanisms that control aging rates in multiple biological systems, then life spans can be extended relatively easily. If not, extending maximum life spans would require changes in impractically large numbers of genes, all genes involved in functional life spans of every biological system. In fact, life spans appear to increase rapidly during evolution, suggesting that changes in only a few genes are required. These genes are likely to control underlying mechanisms timing aging in multiple biological systems. The purpose of selection for increased life span is to identify these genes. An important potential problem is that all species have many defective genetic alleles that can cause early disease and death. Selection studies must be designed to distinguish between altering basic mechanisms of aging, and simply avoiding early pathologies due to defective alleles. Animal models that are short lived for their species should be avoided, because their deaths almost always result from genetic defects unrelated to mechanisms of normal aging. During selection, alleles not causing early pathologies-may appear to increase life spans by replacing defective alleles in genetic regions linked to early pathologies; however, these affect early disease, not basic mechanisms of aging. A more subtle potential problem is that caloric restriction increases life spans in mice. Selection for long lived mice should focus on more basic mechanisms than breeding mice that voluntarily consume fewer calories. The fact that aging rates in different biological systems are not necessarily coordinated in different individuals suggests that normal aging is timed by more than one mechanism. Thus, the objective in selection for maximum longevity is to capture the entire set of alleles that increase longevity in a species. Wild populations are not practical to use, despite some theoretical advantages, as genes retarding aging would be confounded with those reducing the stress of captivity. Currently we use four-way crosses of inbred strains that represent maximal genetic diversity. Genetic regions important in increasing longevity will be identified using microsatellite markers distinguishing each of the four starting strains over the entire genome. Other genetic techniques proven useful for studying characteristics that are quantitatively controlled by multiple genes may also be useful in studying mechanisms timing aging; these techniques include diallele crosses, recombinant inbred lines, bilineal congenic lines and correlated genetic markers.

Published

1997

17. Ocular retardation mouse caused by Chx10 homeobox null allele: impaired retinal progenitor proliferation and bipolar cell differentiation

Author

Danka Vidgen, Roderick R. McInnes, F. Hoover, Daniel Goldman, Sharmila Basu, Margit Burmeister, Lynda Ploder, Thomas H. Roderick, Benjamin A. Taylor, Jakub Novak, Norman L. Hawes, Mei Ying Liang, Vitauts I. Kalnins, and Mark H. Hankin

Subjects

Male, genetic structures, Mammalian eye, Cellular differentiation, Molecular Sequence Data, Gene Expression, Biology, Microphthalmia, Retina, chemistry.chemical_compound, Mice, Genetics, medicine, Animals, Amino Acid Sequence, Eye Abnormalities, Progenitor cell, Alleles, DNA Primers, Base Sequence, Stem Cells, Homozygote, Genes, Homeobox, Chromosome Mapping, Retinal, Cell Differentiation, DNA, medicine.disease, Null allele, eye diseases, Cell biology, medicine.anatomical_structure, chemistry, Mutation, Homeobox, Female, sense organs, Cell Division

Abstract

Ocular retardation (or) is a murine eye mutation causing microphthalmia, a thin hypocellular retina and optic nerve aplasia. Here we show that mice carrying the OrJ allele have a premature stop codon in the homeobox of the Chx10 gene, a gene expressed at high levels in uncommitted retinal progenitor cells and mature bipolar cells. No CHX10 protein was detectable in the retinal neuroepithelium of orJ homozygotes. The loss of CHX10 leads both to reduced proliferation of retinal progenitors and to a specific absence of differentiated bipolar cells. Other major retinal cell types were present and correctly positioned in the mutant retina, although rod outer segments were short and retinal lamination was incomplete. These results indicate that Chx10 is an essential component in the network of genes required for the development of the mammalian eye, with profound effects on retinal progenitor proliferation and bipolar cell specification or differentiation. off

Published

1996

18. New Retinal Degenerations in the Mouse

Author

Norman L. Hawes, John R. Heckenlively, Bo Chang, and Thomas H. Roderick

Subjects

Retinal degeneration, Genetics, Cornea disorder, genetic structures, medicine.diagnostic_test, Glaucoma, Biology, medicine.disease, eye diseases, Ophthalmoscopy, medicine.anatomical_structure, Cataracts, Cornea, medicine, Eye disorder, sense organs, Electroretinography

Abstract

For many years we followed with great interest the comparative advances of genetics in the mouse[l] and in human. [2] Relative frequencies of dominant and recessive traits were similar, mapping of genes proceeded at similar rates, and comparative mapping produced surprises through the discovery of the large number and size of mouse and human homologous chromosomal segments retained since the separation of the species 65 million years ago. What was different between mouse and human was the relative frequency of genetic eye disorders, that is, they were relatively frequent in human, and rare in mouse. Recognizing this was because of bias in ascertainment, because mice do not refer themselves for visual diagnosis and treatment, we began a systematic program to find and characterize mouse eye disorders. The Jackson Laboratory, having the largest collection of mouse mutant stocks and genetically diverse inbred strains was an ideal place to look for genetically determined eye variations and disorders. We have not been disappointed. Through ophthalmoscopy, electroretinography and histology, we have discovered disorders affecting all aspects of the eye including the lid, cornea, iris, lens, and retina, resulting in cornea disorders, cataracts, retinal degenerations and glaucoma. Additional studies have shown predisposition to certain eye problems in aged mice of specific stocks or strains.

Published

1995

19. New mouse primary retinal degeneration (rd-3)

Author

John R. Heckenlively, Bo Chang, Thomas H. Roderick, and Norman L. Hawes

Subjects

Retinal degeneration, Offspring, Locus (genetics), Biology, chemistry.chemical_compound, Mice, Genetic linkage, Retinitis pigmentosa, Genetics, Homologous chromosome, medicine, Electroretinography, Animals, Crosses, Genetic, Gene therapy of the human retina, Retinal Degeneration, Age Factors, Chromosome Mapping, Retinal, Anatomy, medicine.disease, Molecular biology, Mice, Mutant Strains, Disease Models, Animal, Phenotype, chemistry, sense organs

Abstract

A new mouse retinal degeneration that appears to be an excellent candidate for modeling human retinitis pigmentosa is reported. In this degeneration, called rd-3, differentiation proceeds postnatally through 2 weeks, and photoreceptor degeneration starts by 3 weeks. The rod photoreceptor loss is essentially complete by 5 weeks, whereas remnant cone cells are seen through 7 weeks. This is the only mouse homozygous retinal degeneration reported to date in which photoreceptors are initially normal. Crosses with known mouse retinal degenerations rd, Rds, nr, and pcd are negative for retinal degeneration in offspring, and linkage analysis places rd-3 on mouse chromosome 1 at 10 [+-]2.5 cM distal to Akp-1. Homology mapping suggests that the homologous human locus should be on chromosome 1q. 32 refs., 3 figs., 3 tabs.

Published

1993

20. Variable Expressivity of rd-3 Retinal Degeneration Dependent on Background Strain

Author

Chen Peng, Norman L. Hawes, Bo Chang, Thomas H. Roderick, and John R. Heckenlively

Subjects

Retinal degeneration, Retinal pigment epithelium, medicine.diagnostic_test, Biology, medicine.disease, Homology (biology), Indirect ophthalmoscopy, medicine.anatomical_structure, medicine, Human genome, Neutral density filter, Neuroscience, Gene, Electroretinography

Abstract

Mouse models of retinal degeneration are proving to be useful for investigating analogous human conditions; while mice eyes are smaller, they are very similar to human, both morphologically and histologically. It is also possible to examine mouse retinas by indirect ophthalmoscopy and electroretinography, which provides a strong clinical basis for comparing mouse and human conditions.1 Furthermore, because mouse genetics has been studied extensively for the last 60 years, much is known about the homology between mouse and human genes, and genetic discoveries in mouse can quickly lead to inquiries on the same gene in human.

Published

1993

21. Comparative map for mice and humans

Author

Muriel T. Davisson, Patricia Grant, Michael Kosowsky, Donald P. Doolittle, Alan L. Hillyard, Thomas H. Roderick, and Joseph H. Nadeau

Subjects

Genetics, Genome, Genome, Human, MEDLINE, Chromosome Mapping, Hominidae, Biological evolution, Biology, Biological Evolution, Human genetics, Mice, Genes, Species Specificity, Chromosomes, Human, Animals, Humans, Human genome, Gene

Published

1991

22. The hairy ears (Eh) mutation is closely associated with a chromosomal rearrangement in mouse chromosome 15

Author

Ellen C. Akeson, Hope O. Sweet, Muriel T. Davisson, Norman L. Hawes, and Thomas H. Roderick

Subjects

Male, medicine.medical_specialty, Genetic Linkage, Mitosis, Chromosomal translocation, Chromosomal rearrangement, Biology, Chromosome 15, Mice, Meiosis, Genetic linkage, Genetics, medicine, Animals, Crosses, Genetic, Chromosomal inversion, Recombination, Genetic, Cytogenetics, General Medicine, Molecular biology, Mice, Inbred C57BL, Synaptonemal complex, Phenotype, Chromosome Inversion, Mutation, Female

Abstract

SummaryThe mouse mutation hairy ears (Eh) originated in a neutron irradiation experiment at Oak Ridge National Laboratory. Subsequent linkage studies withEhand other loci on Chr 15 suggested that it is associated with a chromosomal rearrangement that inhibits recombination since it shows tight linkage with several loci occupying the region extending from congenital goiter (cog) distal to caracul (ca). We report here (1) linkage experiments confirming this effect on recombination and (2) meiotic and mitotic cytological studies that confirm the presence of a chromosomal rearrangement. The data are consistent with the hypothesis of a paracentric inversion in the distal half of Chr 15. The effect of the inversion extends over a minimum of 30 cM, taking into account the genetic data and the cytologically determined chromosomal involvement extending to the region of the telomere.

Published

1990

23. Chromosomal Localization of a New Mouse Lens Opacity Gene (lop18)

Author

Richard S. Smith, Bo Chang, Norman L. Hawes, John R. Heckenlively, Muriel T. Davisson, and Thomas H. Roderick

Subjects

Male, Brachyury, genetic structures, Opacity, Mouse Lens, Genes, Recessive, Gene mutation, Biology, Cataract, Mice, Gene mapping, Genetic linkage, Lens, Crystalline, Genetics, Animals, Gene, Crosses, Genetic, H-2 Antigens, Chromosome Mapping, Crystallins, eye diseases, Chromosome 17 (human), White (mutation), Mice, Inbred C57BL, Genetic marker, Mice, Inbred CBA, Female, sense organs

Abstract

Examination of mouse strains with a slit lamp and indirect ophthalmoscopy revealed that strain CBA/CaGnLe has a white cataract obvious at weaning age. It soon progresses to a large white nuclear cataract with mild cortical changes. Crosses with C57BL/6J showed that this is inherited as a single recessive fully penetrant gene, which we have designated lop18 (lens opacity 18). Linkage analysis using visible marker T (brachyury), histocompatibility marker H2, and microsatellite markers D17Mit21, D17Mit28, D17Mit38, and D17Mit46 shows that the lop18 gene is located, approximately 16 cM from the centromere on mouse Chromosome 17. It is a likely candidate mutation for the alpha-crystallin (Crya1) gene.

Published

1997

24. Abstracts of meeting presentations (Part 11 of 11)

Author

D. Drayna, Moyra Smith, Frank H. Ruddle, John L. Hamerton, L.A. Menlove, N. Créau-Goldberg, Elizabeth B. Robson, O.J. Miller, R.L. Miller, N.E. Morton, G. Echard, H.F. Willard, Dirk Bootsma, Victor A. McKusick, A. de la Chapelle, P. Meera Khan, Thomas B. Shows, P.A. Lalley, L.U. Lamm, James E. Womack, Susan Povey, S. Naylor, David Cox, P. M. Conneally, P.N. Goodfellow, Phyllis J. McAlpine, Andries Westerveld, Mark H. Skolnick, Stephen J. O'Brien, K.L. Moore, Thomas H. Roderick, Kenneth K. Kidd, Muriel T. Davisson, Roland Berger, Karl-Heinz Grzeschik, C.W. Partridge, Malcolm A. Ferguson-Smith, and P.S. Gerald

Subjects

Genetics, Computational biology, Biology, Molecular Biology, Data science, Genetics (clinical)

Published

1984

25. Mitochondrial malate dehydrogenase (Mor-1) in the mouse: Linkage to chromosome 5 markers

Author

James E. Womack, Eugene R. Soares, Thomas H. Roderick, and Norman L. Hawes

Subjects

Male, Genotype, Genetic Linkage, Locus (genetics), Biology, Kidney, Biochemistry, Malate dehydrogenase, Mice, Gene mapping, Malate Dehydrogenase, Genetic linkage, Genetics, Animals, Molecular Biology, Gene, Alleles, Crosses, Genetic, Ecology, Evolution, Behavior and Systematics, Glucuronidase, ALDH2, Recombination, Genetic, Structural gene, Chromosome Mapping, Chromosome, General Medicine, Molecular biology, Mitochondria, Mice, Inbred C57BL, Mice, Inbred CBA, Female

Abstract

Malate dehydrogenase is present in most mammalian tissues in both supernatant and mitochondrial forms. Although genetic variation for the supernatant form has not been observed in the mouse, electrophoretic variants caused by alleles at the mitochondrial locus (Mor-1) have been previously described. We have located this locus 11.0 +/- 2.9 cM from the beta-glucuronidase structural gene, Gus, on chromosome 5. The gene order is Hm-Pgm-1-rd-bf-Gus-Mor-1. Thus Mor-1 is presently the most distal marker on chromosome 5. Three different nuclear loci for mitochondrial enzymes (Mod-2, Got-2, and Mor-1) have now been mapped in the mouse, all on different chromosomes.

Published

1975

26. A single gene difference determines relative susceptibility to caffeine-induced lethality in SWR and CBA inbred mice

Author

Pamela Johnson, Thomas H. Roderick, John M. Carney, Owen M. Rennert, and Thomas W. Seale

Subjects

Male, Ratón, Clinical Biochemistry, Mice, Inbred Strains, Genetics, Behavioral, Biology, Toxicology, Biochemistry, Mice, Behavioral Neuroscience, chemistry.chemical_compound, Species Specificity, Caffeine, Animals, Allele, Gene, Biological Psychiatry, Pharmacology, Genetics, Autosomal dominant trait, Molecular biology, Phenotype, chemistry, Toxicity, Mice, Inbred CBA, Genes, Lethal, Lethality

Abstract

Inbred mouse strains SWR and CBA differ markedly in their relatively susceptibility to the acute toxic effects of intraperitoneally administered caffeine. At a dose of 187 mg/kg, SWR mice survive a stress-potentiated lethality test apparently related to the generation of tonic seizures; in contrast, CBA mice usually die in less than 30 seconds after this dose. Progeny from several different genetic crosses were characterized to determine the genetic basis underlying this phenotypic difference in caffeine sensitivity. F1 progeny from reciprocal crosses of the parental strains were uniformly sensitive to caffeine-induced lethality, i.e., caffeine responsiveness behaves like an autosomal dominant trait. Self-crossing of F1 individuals produced both progeny which were resistant to caffeine-induced lethality (26% of the total) and those which were susceptible (74%). Backcrosses of the F1 animals to the CBA parent produced no (0/19) resistant progeny. In contrast, backcrosses of F1 animals to SWR produced 54% resistant progeny. These data indicate that the difference in susceptibility to caffeine-induced lethality between these strains is determined by a single pair of autosomal alleles in which susceptibility (responsiveness) to this methylxanthine is dominant to resistance (nonresponsiveness).

Published

1985

27. Subject Index Vol. 32, 1982

Author

Victor A. McKusick, A. de la Chapelle, Phyllis J. McAlpine, Harold P. Klinger, Malcolm A. Ferguson-Smith, Julio Montoya, R.T. Taggart, E.M. Southern, Peter L. Pearson, A. Bernheim, P.S. Gerald, O.J. Miller, D.A. Aitken, L.U. Lamm, Andries Westerveld, Stephen J. O'Brien, L.R. Weitkamp, P. J. L. Cook, Thomas H. Roderick, Mark H. Skolnick, Uta Francke, J.H. Edwards, Roland Berger, Muriel T. Davisson, M Siniscalco, John L. Hamerton, D. Ojala, P.A. Lalley, G. Attardi, Thomas B. Shows, P. Meera Khan, Elizabeth B. Robson, Dirk Bootsma, Ray White, and A. Chomyn

Subjects

Index (economics), Statistics, Genetics, Subject (documents), Biology, Molecular Biology, Genetics (clinical)

Published

1982

28. Contents, Vol. 37, 1984

Author

K.L. Moore, P.A. Lalley, Malcolm A. Ferguson-Smith, Elizabeth B. Robson, Victor A. McKusick, A. de la Chapelle, Kenneth K. Kidd, G. Echard, James E. Womack, Andries Westerveld, Susan Povey, P.S. Gerald, Muriel T. Davisson, L.U. Lamm, Stephen J. O'Brien, N. Créau-Goldberg, P. M. Conneally, H.F. Willard, Thomas H. Roderick, Dirk Bootsma, Mark H. Skolnick, D. Drayna, Roland Berger, David Cox, S. Naylor, Karl-Heinz Grzeschik, L.A. Menlove, Thomas B. Shows, C.W. Partridge, N.E. Morton, O.J. Miller, Frank H. Ruddle, R.L. Miller, P.N. Goodfellow, P. Meera Khan, Moyra Smith, Phyllis J. McAlpine, and John L. Hamerton

Subjects

Botany, Genetics, Zoology, Biology, Molecular Biology, Genetics (clinical)

Published

1984

29. Organic aciduria and butyryl CoA dehydrogenase deficiency in BALB/cByJ mice

Author

Michal Prochazka, P. F. Jezyk, Marc Yudkoff, Stephen P. Schiffer, Donald F. Patterson, and Thomas H. Roderick

Subjects

Butyryl-CoA Dehydrogenase, Fatty Acid Desaturases, Male, Glycine, Biology, Biochemistry, Organic aciduria, Gas Chromatography-Mass Spectrometry, Mice, chemistry.chemical_compound, Autosomal recessive trait, Sex Factors, Species Specificity, Inbred strain, Genetics, Animals, Butyryl-CoA, Molecular Biology, Crosses, Genetic, Ecology, Evolution, Behavior and Systematics, chemistry.chemical_classification, Mice, Inbred BALB C, Butyryl-CoA dehydrogenase, Strain (chemistry), Genetic Variation, General Medicine, Malonates, Isoenzymes, Phenotype, Enzyme, chemistry, Butyryl-CoA Dehydrogenase Deficiency, Female

Abstract

A metabolic screening program of inbred strains of mice has detected a marked organic aciduria in the BALB/cByJ strain. Gas chromatographic and mass spectrometric analysis identified large quantities of n-butyrylglycine plus lesser quantities of ethylmalonic acid. Crosses with the nonexcreting C57BL/6J strain indicate that this condition is inherited as an autosomal recessive trait. Independently from this screening a variant with no detectable enzyme activity of butyryl CoA dehydrogenase (BCD) in liver and kidney of the BALB/cByJ strain but not other BALB/c sublines was discovered. Data from a three-point cross indicated that the null variant maps to the structural locus for the enzyme, Bcd-1, on chromosome 5. The findings indicate that a mutation at or near Bcd-1 in the BALB/cByJ strain resulted in a biochemical abnormality manifest as the BCD deficiency. It is concluded that accumulation of butyryl CoA due to a block in the oxidation of short-chain fatty acids results in an overproduction of organic metabolites leading to the observed organic aciduria. The fact that other BALB/c substrains do not exhibit this abnormality further suggests that this disorder reflects subline divergence within the BALB/c family.

Published

1989

30. Linkage of the locus for conversion of albumin (Acf-1)in the house mouse, Mus musculus

Author

James E. Womack, Frank H. Wilcox, and Thomas H. Roderick

Subjects

Recombination, Genetic, Genetics, Genetic Linkage, Albumin, Chromosome Mapping, Locus (genetics), General Medicine, Biology, biology.organism_classification, digestive system, Biochemistry, Molecular biology, digestive system diseases, House mouse, Mice, Genes, Genetic linkage, Albumins, Animals, Molecular Biology, Gene, Crosses, Genetic, Ecology, Evolution, Behavior and Systematics, Recombination

Abstract

The linkage of the locus for conversion of albumin (Acf-1) has been established on chromosome 1 with the following gene order and recombination percentages: Id-1 19.3 +/- 5.2% Acf-1 4.2 +/- 1.7% Dip-1 18.4 +/- 4.2% Lp.

Published

1979

31. Genetic variation in alkaline phosphatase of the house mouse (Mus musculus) with emphasis on a manganese-requiring isozyme

Author

Benjamin A. Taylor, Frank H. Wilcox, Thomas H. Roderick, James E. Womack, and Lisa R. Hirschhorn

Subjects

Mice, Inbred Strains, Locus (genetics), Biology, Kidney, Biochemistry, Isozyme, law.invention, Mice, Inbred strain, law, Genetic variation, Centromere, Genetics, Animals, Molecular Biology, Gene, Crosses, Genetic, Ecology, Evolution, Behavior and Systematics, Recombination, Genetic, Manganese, Chromosome Mapping, Genetic Variation, General Medicine, Alkaline Phosphatase, Molecular biology, Intestines, Isoenzymes, Genes, Liver, Recombinant DNA, Alkaline phosphatase

Abstract

Genetic variation among inbred strains is described for electrophoretic migration of alkaline phosphatase from intestine, kidney, blood plasma, and three isozymes of liver. A manganese-requiring isozyme of liver and kidney unaffected by neuraminidase is described, and the locus controlling variation in this isozyme is designated Akp-1. Data from recombinant inbred strains place the locus on chromosome 1 at a distance of 3.6±2.9 cM from the Mls locus on the side distal to the centromere. Test-cross data show the following gene order and recombination percentages: $${\text{Dip - 1 }}19.0 \pm 3.8\% {\text{Lp }}7.4 \pm 2.2\% {\text{Akp - 1}}$$

Published

1979

32. Abstracts of meeting presentations (Part 10 of 11)

Author

Andries Westerveld, G. Echard, L.A. Menlove, Kenneth K. Kidd, N.E. Morton, Muriel T. Davisson, David Cox, Dirk Bootsma, D. Drayna, Moyra Smith, N. Créau-Goldberg, P.N. Goodfellow, Victor A. McKusick, Phyllis J. McAlpine, John L. Hamerton, H.F. Willard, A. de la Chapelle, L.U. Lamm, P.S. Gerald, Stephen J. O'Brien, O.J. Miller, Malcolm A. Ferguson-Smith, P. M. Conneally, Thomas H. Roderick, R.L. Miller, K.L. Moore, Frank H. Ruddle, Elizabeth B. Robson, Mark H. Skolnick, Susan Povey, Thomas B. Shows, S. Naylor, James E. Womack, Karl-Heinz Grzeschik, P.A. Lalley, P. Meera Khan, C.W. Partridge, and Roland Berger

Subjects

Genetics, Library science, Biology, Bioinformatics, Molecular Biology, Genetics (clinical)

Published

1984

33. Subject Index Vol. 25, 1979

Author

Malcolm A. Ferguson-Smith, Christine A. Kozak, D.M. Steffensen, T. Douglas, Frank H. Ruddle, John L. Hamerton, M. Shaw, C.W. Partridge, D. Lindsley, Dirk Bootsma, J.K. McDougall, R. Payne, M. Meisler, T. Huisman, David Warburton, L.R. Weitkamp, Thomas B. Shows, John M. Opitz, J.H. Edwards, P. Meera Khan, J.J. Garver, K. Weiss, S. Kit, P. Rubinstein, Harold P. Klinger, Peter L. Pearson, J.R. Gosden, O.J. Miller, Muriel T. Davisson, Elizabeth B. Robson, P.A. Lalley, Victor A. McKusick, Uta Francke, A. de la Chapelle, C.A. Alper, Andries Westerveld, Phyllis J. McAlpine, Jürgen Spranger, Stephen J. O'Brien, Thomas H. Roderick, P. J. L. Cook, N.E. Morton, and Martin E. Dorf

Subjects

Index (economics), Statistics, Genetics, Subject (documents), Biology, Molecular Biology, Genetics (clinical)

Published

1979

34. Contents, Vol. 32, 1982

Author

A. Chomyn, Muriel T. Davisson, J.H. Edwards, P.A. Lalley, O.J. Miller, Peter L. Pearson, Uta Francke, E.M. Southern, P. Meera Khan, P.S. Gerald, Harold P. Klinger, Mark H. Skolnick, L.U. Lamm, L.R. Weitkamp, Ray White, Andries Westerveld, P. J. L. Cook, D. Ojala, Stephen J. O'Brien, Thomas H. Roderick, Elizabeth B. Robson, Roland Berger, Dirk Bootsma, M Siniscalco, Phyllis J. McAlpine, Victor A. McKusick, A. de la Chapelle, A. Bernheim, D.A. Aitken, G. Attardi, Malcolm A. Ferguson-Smith, Julio Montoya, R.T. Taggart, John L. Hamerton, and Thomas B. Shows

Subjects

Botany, Genetics, Zoology, Biology, Molecular Biology, Genetics (clinical)

Published

1982

35. Abstracts of meeting presentations (Part 6 of 11)

Author

L.A. Menlove, P. Meera Khan, N.E. Morton, Frank H. Ruddle, Kenneth K. Kidd, Muriel T. Davisson, L.U. Lamm, Andries Westerveld, S. Naylor, Mark H. Skolnick, Victor A. McKusick, A. de la Chapelle, Moyra Smith, P. M. Conneally, N. Créau-Goldberg, H.F. Willard, Karl-Heinz Grzeschik, K.L. Moore, C.W. Partridge, P.A. Lalley, James E. Womack, Stephen J. O'Brien, P.N. Goodfellow, Thomas H. Roderick, Phyllis J. McAlpine, Malcolm A. Ferguson-Smith, John L. Hamerton, Thomas B. Shows, Roland Berger, D. Drayna, David Cox, O.J. Miller, R.L. Miller, G. Echard, P.S. Gerald, Elizabeth B. Robson, Dirk Bootsma, and Susan Povey

Subjects

Genetics, Computational biology, Biology, Molecular Biology, Data science, Genetics (clinical)

Published

1984

36. Abstracts of meeting presentations (Part 2 of 5)

Author

P.A. Lalley, Malcolm A. Ferguson-Smith, P. J. L. Cook, N.E. Morton, Victor A. McKusick, Phyllis J. McAlpine, A. de la Chapelle, C.A. Alper, Christine A. Kozak, S. Kit, K. Weiss, J.J. Garver, P. Rubinstein, M. Shaw, David Warburton, O.J. Miller, P. Meera Khan, Harold P. Klinger, Martin E. Dorf, D.M. Steffensen, L.R. Weitkamp, Thomas B. Shows, C.W. Partridge, Andries Westerveld, Frank H. Ruddle, T. Douglas, Uta Francke, John L. Hamerton, T. Huisman, J.H. Edwards, J.K. McDougall, John M. Opitz, Stephen J. O'Brien, Thomas H. Roderick, J.R. Gosden, R. Payne, Muriel T. Davisson, Elizabeth B. Robson, Dirk Bootsma, Jürgen Spranger, D. Lindsley, Peter L. Pearson, and M. Meisler

Subjects

Genetics, Computational biology, Biology, Molecular Biology, Data science, Genetics (clinical)

Published

1979

37. Abstracts of meeting presentations (Part 4 of 11)

Author

L.U. Lamm, P.S. Gerald, S. Naylor, Frank H. Ruddle, James E. Womack, Dirk Bootsma, P. M. Conneally, Roland Berger, G. Echard, Andries Westerveld, John L. Hamerton, N. Créau-Goldberg, O.J. Miller, Kenneth K. Kidd, L.A. Menlove, R.L. Miller, Malcolm A. Ferguson-Smith, Muriel T. Davisson, H.F. Willard, N.E. Morton, Elizabeth B. Robson, Susan Povey, Phyllis J. McAlpine, David Cox, Moyra Smith, P.N. Goodfellow, D. Drayna, Stephen J. O'Brien, Thomas H. Roderick, Victor A. McKusick, A. de la Chapelle, Thomas B. Shows, Mark H. Skolnick, K.L. Moore, P.A. Lalley, Karl-Heinz Grzeschik, P. Meera Khan, and C.W. Partridge

Subjects

Genetics, Library science, Biology, Bioinformatics, Molecular Biology, Genetics (clinical)

Published

1984

38. Abstracts of meeting presentations (Part 3 of 5)

Author

Peter L. Pearson, P. Rubinstein, Thomas B. Shows, Victor A. McKusick, P. J. L. Cook, Andries Westerveld, D. Lindsley, Elizabeth B. Robson, A. de la Chapelle, Stephen J. O'Brien, N.E. Morton, Frank H. Ruddle, C.A. Alper, Thomas H. Roderick, Dirk Bootsma, John L. Hamerton, P.A. Lalley, J.R. Gosden, Malcolm A. Ferguson-Smith, Martin E. Dorf, J.K. McDougall, Phyllis J. McAlpine, S. Kit, Christine A. Kozak, P. Meera Khan, T. Douglas, R. Payne, David Warburton, K. Weiss, Jürgen Spranger, M. Shaw, D.M. Steffensen, J.J. Garver, L.R. Weitkamp, C.W. Partridge, Harold P. Klinger, M. Meisler, Muriel T. Davisson, O.J. Miller, Uta Francke, T. Huisman, J.H. Edwards, and John M. Opitz

Subjects

Genetics, Library science, Biology, Bioinformatics, Molecular Biology, Genetics (clinical)

Published

1979

39. Abstracts of meeting presentations (Part 1 of 4)

Author

Susan Povey, Moyra Smith, Frank H. Ruddle, Thomas B. Shows, Elizabeth B. Robson, Dirk Bootsma, O.J. Miller, Malcolm A. Ferguson-Smith, R.L. Miller, P.A. Lalley, John L. Hamerton, L.U. Lamm, L.A. Menlove, Phyllis J. McAlpine, C.W. Partridge, D. Drayna, Stephen J. O'Brien, N.E. Morton, P. M. Conneally, Victor A. McKusick, Thomas H. Roderick, P.S. Gerald, G. Echard, A. de la Chapelle, Kenneth K. Kidd, James E. Womack, Muriel T. Davisson, S. Naylor, P. Meera Khan, David Cox, K.L. Moore, Roland Berger, P.N. Goodfellow, Mark H. Skolnick, Karl-Heinz Grzeschik, N. Créau-Goldberg, H.F. Willard, and Andries Westerveld

Subjects

Genetics, Library science, Biology, Bioinformatics, Molecular Biology, Genetics (clinical)

Published

1982

40. Abstracts of meeting presentations (Part 2 of 4)

Author

Susan Povey, Karl-Heinz Grzeschik, Phyllis J. McAlpine, Frank H. Ruddle, P.S. Gerald, Kenneth K. Kidd, L.A. Menlove, Muriel T. Davisson, N. Créau-Goldberg, D. Drayna, N.E. Morton, H.F. Willard, Dirk Bootsma, P.A. Lalley, Roland Berger, L.U. Lamm, Stephen J. O'Brien, James E. Womack, Thomas H. Roderick, P. M. Conneally, Thomas B. Shows, Malcolm A. Ferguson-Smith, David Cox, Mark H. Skolnick, C.W. Partridge, Andries Westerveld, S. Naylor, K.L. Moore, P. Meera Khan, O.J. Miller, P.N. Goodfellow, R.L. Miller, G. Echard, John L. Hamerton, Moyra Smith, Elizabeth B. Robson, Victor A. McKusick, and A. de la Chapelle

Subjects

Genetics, Computational biology, Biology, Molecular Biology, Data science, Genetics (clinical)

Published

1982

41. Mouse chromosome fragility

Author

Maureen M. Sanz, Edmund C. Jenkins, W. Ted Brown, Muriel T. Davisson, Monica J. Kevin, Thomas H. Roderick, Wayne P. Silverman, Henryk M. Wisniewski, John M. Opitz, and James F. Reynolds

Subjects

Genetic Markers, Genetics, Chromosome Fragile Sites, Chromosome Fragility, Strain (biology), Chromosomal fragile site, Chromosome, Mice, Inbred Strains, Karyotype, Biology, Molecular biology, Chromosome Banding, Mice, Species Specificity, Chromosome Fragile Site, Genetic marker, Genetic linkage, Animals, Floxuridine, Cells, Cultured, Genetics (clinical)

Abstract

When cultures of fibroblast-like cells from inbred mouse strains RBC/Dn and AEJ/GnRk were exposed to 5-fluoro-deoxyuridine (FUdR), non-random strain-specific distributions of chromosome gaps, breaks and exchanges were observed. Throughout the genomes there appeared to be specific sites at which lesions occurred preferentially. Two strain-specific fragile sites were identified in strain RBC/Dn at G-band 15A2, and at G-band 19B in strain AEJ/GnRk. Constitutive fragile sites at G-bands 12A2 and 18A2 were identified in both strains. A strain-specific marker at G-band 9B was found in strain AEJ/GnRk. The fragile sites reported here provide an animal model for the study of chromosome fragility as well as polymorphic markers for linkage studies.

Published

1986

42. Juvenile Spermatogonial Depletion (jsd): A Genetic Defect of Germ Cell Proliferation of Male Mice1

Author

Kathryn L. Shultz, Wesley G. Beamer, Terrie L. Cunliffe-Beamer, Stephen H. Langley, and Thomas H. Roderick

Subjects

medicine.medical_specialty, Mutant, Vas deferens, Cell Biology, General Medicine, Biology, Sertoli cell, Sperm, medicine.anatomical_structure, Germ cell proliferation, Endocrinology, Seminal vesicle, Reproductive Medicine, Internal medicine, medicine, Spermatogenesis, Testosterone

Abstract

Adult C57BL/6J male mice homozygous for the mutant gene, juvenile spermatogonial depletion (jsd/jsd), show azoosper4ia and testes reduced to one-third normal size, but are otherwise phenotypically normal. In contrast, adult jsd/jsd females are fully fertile. This feature facilitated mapping the jsd gene to the centromeric end of chromosome 1; the gene order is jsd-Isocitrate dehydrogenase-1 (Idh-1)-Peptidase-3 (Pep-3). Analysis of testicular histology from jsd/jsd mice aged 3-10 wk revealed that these mutant mice experience one wave of spermatogenesis, but fail to continue mitotic proliferation of type A spermatogonial cells at the basement membrane. As a consequence, histological sections of testes from mutant mice aged 8-52 wk showed tubules populated by modest numbers of Sertoli cells, with only an occasional spermatogonial cell. Some sperm with normal morphology and motility were observed in epididymides of 6.5- but not in 8-wk or older mutants. Treatment with retinol failed to alter the loss of spermatogenesis in jsd/jsd mice. Analyses of serum hormones of jsd/jsd males showed that testosterone levels were normal at all ages--a finding corroborated by normal seminal vesicle and vas deferens weights, whereas serum follicle-stimulating hormone levels were significantly elevated in mutant mice from 4 to 20 wk of age. We hypothesize the jsd/jsd male may be deficient in proliferative signals from Sertoli cells that are needed for spermatogenesis.

Published

1988

43. Abstracts of meeting presentations (Part 5 of 5)

Author

T. Huisman, P. Rubinstein, P.A. Lalley, John L. Hamerton, Phyllis J. McAlpine, D. Lindsley, R. Payne, Martin E. Dorf, J.H. Edwards, M. Shaw, L.R. Weitkamp, J.K. McDougall, Elizabeth B. Robson, K. Weiss, J.J. Garver, S. Kit, M. Meisler, John M. Opitz, Harold P. Klinger, Jürgen Spranger, Christine A. Kozak, J.R. Gosden, P. Meera Khan, Malcolm A. Ferguson-Smith, Andries Westerveld, Thomas B. Shows, Peter L. Pearson, Dirk Bootsma, David Warburton, Stephen J. O'Brien, Thomas H. Roderick, Muriel T. Davisson, Frank H. Ruddle, P. J. L. Cook, C.W. Partridge, N.E. Morton, D.M. Steffensen, T. Douglas, Victor A. McKusick, A. de la Chapelle, C.A. Alper, O.J. Miller, and Uta Francke

Subjects

Genetics, Computational biology, Biology, Molecular Biology, Data science, Genetics (clinical)

Published

1979

44. Abstracts of meeting presentations (Part 7 of 11)

Author

James E. Womack, C.W. Partridge, Frank H. Ruddle, O.J. Miller, P.N. Goodfellow, David Cox, S. Naylor, R.L. Miller, P.S. Gerald, K.L. Moore, L.U. Lamm, Moyra Smith, Karl-Heinz Grzeschik, Stephen J. O'Brien, D. Drayna, L.A. Menlove, Thomas H. Roderick, John L. Hamerton, Victor A. McKusick, N.E. Morton, P. M. Conneally, A. de la Chapelle, Mark H. Skolnick, Kenneth K. Kidd, P. Meera Khan, Muriel T. Davisson, G. Echard, P.A. Lalley, Roland Berger, Malcolm A. Ferguson-Smith, Thomas B. Shows, Susan Povey, Dirk Bootsma, Phyllis J. McAlpine, Andries Westerveld, Elizabeth B. Robson, N. Créau-Goldberg, and H.F. Willard

Subjects

Genetics, Library science, Biology, Bioinformatics, Molecular Biology, Genetics (clinical)

Published

1984

45. Abstracts of meeting presentations (Part 8 of 11)

Author

P.A. Lalley, L.A. Menlove, O.J. Miller, James E. Womack, R.L. Miller, Thomas B. Shows, D. Drayna, N.E. Morton, L.U. Lamm, Mark H. Skolnick, David Cox, Andries Westerveld, Phyllis J. McAlpine, John L. Hamerton, Frank H. Ruddle, P. M. Conneally, N. Créau-Goldberg, Stephen J. O'Brien, K.L. Moore, H.F. Willard, P.S. Gerald, Moyra Smith, Victor A. McKusick, Thomas H. Roderick, Karl-Heinz Grzeschik, S. Naylor, A. de la Chapelle, C.W. Partridge, Malcolm A. Ferguson-Smith, G. Echard, P. Meera Khan, Kenneth K. Kidd, Muriel T. Davisson, P.N. Goodfellow, Roland Berger, Elizabeth B. Robson, Dirk Bootsma, and Susan Povey

Subjects

Genetics, Library science, Biology, Bioinformatics, Molecular Biology, Genetics (clinical)

Published

1984

46. Abstracts of meeting presentations (Part 9 of 11)

Author

James E. Womack, Victor A. McKusick, A. de la Chapelle, K.L. Moore, Dirk Bootsma, L.U. Lamm, P.A. Lalley, L.A. Menlove, Thomas B. Shows, C.W. Partridge, O.J. Miller, N.E. Morton, P. M. Conneally, R.L. Miller, Stephen J. O'Brien, Phyllis J. McAlpine, Karl-Heinz Grzeschik, Thomas H. Roderick, Elizabeth B. Robson, Moyra Smith, John L. Hamerton, Susan Povey, Andries Westerveld, P. Meera Khan, S. Naylor, Malcolm A. Ferguson-Smith, D. Drayna, P.S. Gerald, Kenneth K. Kidd, Muriel T. Davisson, P.N. Goodfellow, Mark H. Skolnick, David Cox, Frank H. Ruddle, G. Echard, N. Créau-Goldberg, H.F. Willard, and Roland Berger

Subjects

Genetics, Library science, Biology, Bioinformatics, Molecular Biology, Genetics (clinical)

Published

1984

47. Complex genetic determinants of susceptibility to methylxanthine-induced locomotor activity changes

Author

Thomas H. Roderick, Owen M. Rennert, Lance Logan, John M. Carney, Pamela Johnson, and Thomas W. Seale

Subjects

Male, Clinical Biochemistry, Mice, Inbred Strains, Stimulation, Genetics, Behavioral, Motor Activity, Quantitative trait locus, Biology, Toxicology, Biochemistry, Mice, Behavioral Neuroscience, chemistry.chemical_compound, Neurochemical, Theophylline, Caffeine, medicine, Animals, Biological Psychiatry, Pharmacology, Genetics, Dose-Response Relationship, Drug, Autosomal dominant trait, chemistry, Xanthines, Backcrossing, Mice, Inbred CBA, Inbreeding, medicine.drug

Abstract

The intent of this study was to investigate the role of inheritance in the determination of susceptibility to methylxanthine-induced behavioral changes. Two strains of inbred mice, SWR and CBA, which differ significantly in their response to caffaine- and theophylline-induced stimulation of locomotor activity, were used in classical genetic crosses to produce reciprocal F1 hybrids, reciprocal backcross progeny and F2 progeny. Theophylline dose reponse curves in the reciprocal F1 hybrid strains were identical to each other and to their methylxanthine-responsive (CBA) parent. These results indicated that theophylline responsiveness behaved as a simple autosomal dominant trait. Behavioral responses of these F1 hybrid strains to caffeine showed the same maximal enhancement of locomotor activity as their CBA progenitor at a dose 10 mg/kg IP, but locomotor activity stimulation also occurred at 32 mg/kg IP, a dose which inhibited their CBA parent. These data suggest that the genes specifying caffeine responsiveness differ from those encoding theophylline responsiveness. For both caffeine and theophylline, behavioral phenotypes and their expected frequencies of occurrence among backcross and F2 progeny differed significantly from the segregation ratios expected for a trait determined by a single gene. These non-Mendelian segregation ratios suggest that locomotor activity stimulation by both of these methylxanthines is polygenically determined. It was anticipated that the same genetically encoded neurochemical mechanism would underlie the difference in behavioral response to the two methylxanthines. However, no significant correlation between caffeine-induced and theophylline-induced stimulation of locomotor activity was observed among progeny derived from backcrosses of F1 self-crosses. These data establish that the behavioral effects of methylxanthines on locomotor activity levels are inherited in a complex manner and that, at least in these two strains of inbred mice, different genetic or genetically encoded neurochemical mechanisms underlie the behavioral effects of caffeine and theophylline.

Published

1986

48. Contents, Vol. 25, 1979

Author

Malcolm A. Ferguson-Smith, Frank H. Ruddle, J.R. Gosden, P.A. Lalley, T. Huisman, J.H. Edwards, P. J. L. Cook, Stephen J. O'Brien, Thomas H. Roderick, Victor A. McKusick, A. de la Chapelle, K. Weiss, N.E. Morton, M. Shaw, C.A. Alper, Elizabeth B. Robson, L.R. Weitkamp, D.M. Steffensen, T. Douglas, O.J. Miller, Martin E. Dorf, D. Lindsley, David Warburton, P. Rubinstein, Uta Francke, M. Meisler, Jürgen Spranger, Peter L. Pearson, Andries Westerveld, John L. Hamerton, P. Meera Khan, Christine A. Kozak, J.K. McDougall, Thomas B. Shows, C.W. Partridge, R. Payne, J.J. Garver, Phyllis J. McAlpine, Harold P. Klinger, John M. Opitz, Muriel T. Davisson, S. Kit, and Dirk Bootsma

Subjects

Botany, Genetics, Biology, Molecular Biology, Genetics (clinical)

Published

1979

49. ESTERASE GENETICS IN MUS MUSCULUS: EXPRESSION, LINKAGE, AND POLYMORPHISM OF LOCUS Es-2

Author

Thomas B. Shows, Thomas H. Roderick, and Frank H. Ruddle

Subjects

Electrophoresis, Genetics, Polymorphism, Genetic, Esterases, Chromosome Mapping, Polymorphism (biology), Locus (genetics), Investigations, Biology, Kidney, Esterase, Phenotype, Isozyme, Molecular biology, Isoenzymes, Mice, Animals, Molecular Biology

Published

1969

50. Contents, Vol. 12, 1973

Author

G.M. Martin, C.W. Gray, Doris H. Wurster-Hill, Pertti Aula, Thomas H. Roderick, Sen Pathak, P.H. Fitzgerald, I.L. Firschein, Frederick E. Warburton, Frances E. Arrighi, P. de Boer, H. Hoehn, Harriet von Koskull, Muriel T. Davisson, Dorothy A. Miller, and Dorothy Warburton

Subjects

Botany, Genetics, Zoology, Biology, Molecular Biology, Genetics (clinical)

Published

1973