Both isoforms of ketohexokinase are dispensable for normal growth and development.

Dietary fructose intake has dramatically increased over recent decades and is implicated in the high rates of obesity, hypertension, and type 2 diabetes (metabolic syndrome) in Western societies. The molecular determinants of this epidemiologic correlation are incompletely defined, but high-flux fructose catabolism initiated by ketohexokinase (Khk, fructokinase) is believed to be important. The Khk gene encodes two enzyme isoforms with distinctive substrate preferences, the independent physiological roles of which are unclear. To investigate this question, and for testing the importance of Khk in metabolic syndrome, isoform-selective genetic lesions would be valuable. Two deficiency alleles of the mouse Khk gene were designed. The first, Khk(3a), uses targeted "knock-in" of a premature termination codon to induce a selective deficiency of the minor Khk-A isoform, preserving the major Khk-C isoform. The second, the Khk(Δ) allele, ablates both isoforms. Mice carrying each of these Khk-deficiency alleles were generated and validated at the DNA, RNA, and protein levels. Comparison between normal and knockout animals confirmed the specificity of the genetic lesions and allowed accurate analysis of the cellular distribution of Khk within tissues such as gut and liver. Both Khk(3a/3a) and Khk(Δ/Δ) homozygous mice were healthy and fertile and displayed minimal biochemical abnormalities under basal dietary conditions. These studies are the first demonstration that neither Khk isoform is required for normal growth and development. The new mouse models will allow direct testing of various hypotheses concerning the role of this enzyme in metabolic syndrome in humans and the value of Khk as a pharmacological target.

The specificity of the myelin basic protein gene promoter studied in transgenic mice.

The myelin basic proteins (MBPs) are a family of polypeptides that are predominantly expressed in the nervous system where they play a major role in myelination. We have generated four lines of transgenic mice carrying a transgene in which 1.34 kb of the 5'-flanking sequence of the mouse MBP gene was fused upstream of the coding region of the Escherichia coli lac Z gene in order to investigate developmental and tissue-specific expression of the MBP gene. Expression of both the lacZ transgene and the endogenous MBP gene followed a common developmental pattern in mouse brain. Transgene expression was detected in primary oligodendrocytes, but not in type 2 astrocytes. In addition, the lacZ gene product was expressed in epithelial cells of certain nonneural tissues, namely kidney, epididymis, ureter, and seminal vesicles. The ectopic expression of the transgene was associated with the development of DNase I hypersensitive sites at the site of insertion which was found to be within the intron 1 region of the endogenous MBP gene. The results reported here strongly suggest that the 1.34-kb 5'-flanking region of the MBP gene contains cis-regulatory elements that confer developmental regulation of the MBP gene, although this region appears to lack elements that restrict its expression to the nervous system.

Cell-type specific factors bind to regulatory elements located downstream of the TATA-box element in the mouse myelin basic protein (MBP) gene promoter.

Cell-type specific transcription of the myelin basic protein (MBP) gene in primary oligodendrocytes (OL) is regulated by cis-acting regulatory elements located at both upstream and downstream of the TATA-box region of the MBP promoter. To identify cell-type specific factors that bind to the downstream regulatory elements, we utilised DNase I footprinting analysis and gel retardation assays with nuclear extracts from myelin-forming OL as well as a non-myelin forming cell line, C6 glioma (C6) cells. Several regions of DNA were protected from DNAse I digestion by nuclear extracts of both cell types. However, two regions, from -17 to +17 and from +47 to +58 were protected specifically in OL, while three regions, from + 17 to + 22, from +43 to +49 and from +58 to +64 were protected only with C6 nuclear extracts. Inspection of the protected regions for homology with known transcription factor binding sites revealed that sequences at from +47 to +58 and from +56 to +68 showed extensive homology to the negative regulatory element (NRE1), of the mouse renin gene and to the interferon (IFN) consensus sequence of major histocompatibility complex class I genes (MHC I-ICS), respectively. Gel retardation assays using a MHC I-ICS oligonucleotide and transient transfection assays using MBP-CAT constructs were used to study the effect of IFNs on MBP promoter activity in OL and C6 cells. In OL, IFN-alpha/beta caused little induction of CAT activity, but IFN-gamma resulted in a 2-3.5-fold decrease in CAT activity. In contrast, in C6 cells both IFN-alpha/beta and IFN-gamma induced a 1.5-2.5-fold increase in CAT activity. The cooperative effects of factors binding to NREs and ICS may be responsible for the cell-type specific regulation of MBP gene transcription.

Stable and temperature-sensitive transformation of baby rat kidney cells by SV40 suppresses expression of membrane dipeptidase.

Membrane dipeptidase (MDP) is a zinc metalloenzyme located in the lungs and on the brush border membranes of the kidney and intestine. The gene for MDP (also termed DPEP1) is both frequently lost in Wilm's tumours and is located on human chromosome 16q24.3, a region of the genome known to contain a tumour suppressor gene(s). We now report on the regulation of MDP gene expression in normal and transformed cells. MDP enzyme activity and mRNA was detected in primary baby rat kidney (BRK) cells maintained in culture for up to 4 weeks. In contrast all stable transformed cell lines that were tested, derived either by transformation with the DNA tumour viruses SV40 or adenovirus, or in human tumour cell lines, contained very low levels of or no detectable MDP mRNA or enzyme activity. In BRK cells transformed by the temperature-sensitive tsA58 mutant of SV40 T antigen, MDP activity was not detectable, in cell lines grown at the permissive temperature (33 degrees C) but after 5-14 days of incubation at the non-permissive temperature (39.5 degrees C), MDP protein and enzyme activity could be readily detected. Taken together, these results indicate that MDP expression is characteristic of differentiated kidney epithelial cells and is down-regulated in proliferating, transformed cells.

Regulation of myelin basic protein-encoding gene transcription in rat oligodendrocytes.

The myelin (My) basic protein-encoding gene (MBP) is specifically expressed by oligodendrocytes (OL) in the central nervous system (CNS) and by Schwann cells in the peripheral nervous system (PNS). To define cell-type-specific regulatory elements, a series of chimaeric constructs containing varying lengths of the 5'-flanking region and exon 1 of MBP linked to the cat reporter gene was transfected into several cell types, including primary cultures of differentiated rat OL, Schwann cells and kidney cells, as well as neuronal and non-neuronal cell lines. All the constructs generated variable levels of chloramphenicol acetyltransferase (CAT) activity in all cell types, except in primary OL and Schwann cells, where distinct positive (PRE) and negative regulatory elements (NRE) were found to be involved in regulating cat expression. The nucleotide (nt) -53/+70 construct gave maximal activity in all cell types, except OL and Schwann cells, where sequences upstream from nt -53 were necessary for maximal promoter activity. The sequences located at nt -655 to -397 and nt -394 to -54 showed enhancer and repressor effects, respectively, in OL. In Schwann cells, sequences from -394 to -253 showed positive regulatory effects, while those between -655 to -397 and -253 to -54 showed negative regulatory effects. In the downstream region of the promoter, sequences from +20 to +70 and +70 to +200 showed strong silencer and enhancer activities specifically in OL. In gel-retardation assays using nuclear extracts prepared from several cell types and the -253 to -53 repressor sequences, specific DNA-protein complexes unique to OL were identified.(ABSTRACT TRUNCATED AT 250 WORDS)