Subject(s)
Clinical Clerkship/organization & administration , Ethics, Medical , Genetic Testing , Genetics, Medical/education , Patient Care Team/organization & administration , Attitude of Health Personnel , Clinical Competence/standards , Curriculum , Genetic Counseling , Humans , Nurse Practitioners/education , Nurse Practitioners/psychology , Program Evaluation , Public Health , Students, Health Occupations/psychology , Students, Medical/psychology , Students, Nursing/psychology , Surveys and QuestionnairesSubject(s)
Amino Acid Metabolism, Inborn Errors/genetics , Mutation , Ornithine Carbamoyltransferase/genetics , Ammonia/blood , Binding Sites , Child, Preschool , Codon, Terminator , DNA Probes , Exons/genetics , Female , Humans , Ornithine/metabolism , Ornithine Carbamoyltransferase/metabolism , Ornithine Carbamoyltransferase Deficiency Disease , Orotic Acid/urineABSTRACT
Gene transfer using yeast artificial chromosome (YAC) clones provides an opportunity to study the expression of several linked genes within an environment more closely approximating their normal chromosomal context. A YAC clone spanning 330 kb of the HLA class II region from centromeric of TAP 1 to telomeric of HLA-DQA1 was retrofitted by homologous recombination with a neomycin plasmid targeted either to an Alu repeat sequence within the YAC genomic insert or to the Ura-3 gene within the right arm of the YAC vector. The modified YAC clones were transferred to Chinese hamster ovary or L cells by spheroplast fusion. Eight of 14 Alu-retrofitted and 10 of 15 right arm-retrofitted neomycin clones retained the six human loci known to be encoded by the YAC as well as portions of the left and right YAC vector arms. All tested L cell transformants showed IFN-gamma-inducible TAP 1 and TAP 2 mRNA expression. Two of eight analyzed clones expressed HLA-DQB mRNA and one of four expressed HLA-DQA. Cells expressing both the HLA-DQA and -DQB mRNA showed HLA-DQ cell surface expression. These studies establish the feasibility of introducing groups of functional genes into mammalian cells by spheroplast fusion with a single YAC clone.
Subject(s)
Genes, MHC Class II , Transfection , Animals , Base Sequence , CHO Cells , Cell Fusion , Chromosomes, Fungal , Cricetinae , HLA-DQ Antigens/analysis , HLA-DQ Antigens/genetics , Humans , Interferon-gamma/pharmacology , L Cells , Mice , Molecular Sequence Data , RNA, Messenger/analysis , Yeasts/geneticsABSTRACT
Cellular retinol binding protein II (CRBP II) is an abundant, 134-residue protein present in the small intestinal epithelium. It is thought to participate in the uptake and/or intracellular metabolism of vitamin A. We have isolated and sequenced the rat CRBP II gene. Its four exons span 0.65 kilobases and are interrupted by three introns with an aggregate length of 19.5 kilobases. Southern blot hybridization analysis indicated that this gene is highly conserved in rats, mice, and humans. CRBP II belongs to a protein family that contains eight known members. Computer-assisted comparative sequence analyses indicated that a region of internal homology spans its first two exons and that oligopeptide domains specified by these first two exons exhibit significant homology to all other family members as well as to a portion of the all-trans-retinol binding domain that has previously been defined in serum retinol binding protein. The CRBP II gene was mapped in mice using recombinant inbred strains and restriction fragment length polymorphisms. It is located on chromosome 9 within 5.3 centimorgans of the phosphoglucomutase-3 locus and is closely linked (within 3.0 centimorgans) to the gene specifying a highly homologous intracellular retinol binding protein known as CRBP. Mouse-human somatic cell hybrids were used to determine that both the CRBP and CRBP II genes are located on human chromosome 3.
Subject(s)
Genetic Linkage , Retinol-Binding Proteins/genetics , Amino Acid Sequence , Animals , Base Sequence , Chickens , Computers , DNA Restriction Enzymes/metabolism , Fishes , Humans , Mice , Mice, Inbred C57BL , Nucleic Acid Hybridization , Rats , Retinol-Binding Proteins, Cellular , Transcription, GeneticABSTRACT
Expression of the apolipoprotein B (apoB) gene was examined in a variety of fetal, neonatal, and adult rat tissues by probing RNA blots with a cloned rat apoB cDNA. Among 10 adult male tissues surveyed, small intestine had the highest concentration of apoB mRNA. Its abundance in liver and adrenal gland was 40% and 0.5%, respectively, of that in small bowel, while none was detected in colon, kidney, testes, spleen, lung, heart, or brain. ApoB mRNA is as abundant in 18-day fetal liver as at any subsequent period of hepatic development. In contrast, the concentration of apoB mRNA remains low in fetal intestine until the last (21st) day of gestation, when it increases sharply to levels that are several-fold higher than in the liver. ApoB mRNA levels in fetal membranes harvested during this late gestational period were 10 times greater than in fetal liver. Since the major lipoprotein species in 19-day fetal plasma is low density lipoprotein, these observations suggest that fetal liver, and particularly its functional homologue, the yolk sac, are the principal sites of fetal lipoprotein synthesis at this stage of development. A 20-fold increase in placental apoB mRNA concentrations during the last 48 hr of pregnancy (to a level that is 50% of that encountered in fetal membrane RNA) suggests a specific role for this organ in maternal-fetal lipid transport immediately prior to parturition. Pulse-labeling experiments using 21-day fetal tissue slices showed that the liver synthesizes both apoB-100 (B-PI) and apoB-48 (B-PIII) albeit in somewhat different ratios than the adult organ. Fetal intestine produces almost exclusively the smaller apoB species, while fetal membranes and placenta synthesize only the larger peptide. The postnatal pattern of apoB mRNA accumulation is similar in liver and intestine. Profound decreases were observed during the late suckling and weaning periods, followed by an increase to adult levels. These final concentrations were similar to those encountered at birth. Analysis of these developmental changes offers an opportunity to generate testable hypotheses about the factors that modulate apoB synthesis.
Subject(s)
Apolipoproteins B/genetics , Gene Expression Regulation , Age Factors , Animals , Animals, Newborn/metabolism , Female , Fetus/analysis , Intestines/analysis , Lipoproteins, LDL/metabolism , Lipoproteins, VLDL/metabolism , Liver/analysis , Male , Placenta/analysis , Pregnancy , RNA, Messenger/analysis , Rats , Rats, Inbred StrainsABSTRACT
The primary structure of rat cellular retinol-binding protein (CRBP) II has been determined from a cloned cDNA. Alignment of this 134-amino acid, 15,580-Da polypeptide with rat CRBP revealed that 75 of 133 comparable residues are identical. Both proteins contain four tryptophan residues, which occupy identical relative positions in the two primary structures, providing a structural explanation for their similar fluorescence spectra when complexed to retinol. Two of the three cysteines in each single-chain protein are comparably positioned. Both polypeptides contain reactive thiol groups, but the rate of disruption of CRBP II-retinol complexes by p-chloromercuribenzoate is greater than that of CRBP-retinol. The small intestine contains the highest concentrations of CRBP II mRNA in adult rats. CRBP II mRNA is first detectable in intestinal RNA during the 19th day of gestation, a time that corresponds to the appearance of an absorptive columnar epithelium. Unlike in intestine, a dramatic fall in liver CRBP II mRNA concentration occurs immediately after birth. The CRBP II gene remains quiescent in the liver during subsequent postnatal development. These data suggest that ligand-protein interactions may be somewhat different for the two rat CRBPs. They also support the concept that CRBP II plays a role in the intestinal absorption or esterification of retinol and suggest that changes in hepatic metabolism of vitamin A occur during development.
