Interaction between the zinc (II) and the heparin binding site of the Alzheimer's disease beta A4 amyloid precursor protein (APP).

The Alzheimer's disease beta A4 amyloid precursor protein (APP) has been suggested to be involved in regulation of cell growth, neurite outgrowth and adhesiveness through binding to heparin sulfate proteoglycans. In order to unravel the molecular mechanisms underlying those functions in vitro we show that APP binds in a time dependent and saturable manner to the glycosaminoglycan side-chains of proteoglycans but not to chondroitinsulfate. We also demonstrate an interaction between the high affinity heparin binding site within the carbohydrate domain of APP and the zinc(II) binding site of APP. We show that the affinity for heparin is increased two- to four-fold in the presence of micromolar zinc(II). Thus micromolar concentrations of zinc(II) appear to be able to modulate the binding of APP to heparin side-chains of proteoglycans and as shown previously [Science 265 (1994) 1464-1467] to induce the aggregation of soluble amyloid beta A4 protein.

Regulation and expression of the Alzheimer's beta/A4 amyloid protein precursor in health, disease, and Down's syndrome.

A four- to fivefold overexpression of the gene for the Alzheimer beta/A4 amyloid precursor protein (APP) in individuals with Down's Syndrome (DS) appears to be responsible for the fifty year earlier onset of Alzheimer's disease (AD) pathology in DS compared to the normal population. It is therefore likely that a deregulated overexpression of the APP gene is a risk factor for the beta/A4 amyloid formation. To test this hypothesis and to get a better understanding of how APP expression is regulated, we studied the 5' control region of the human APP gene, alternative splicing of the 19 APP exons, and APP biogenesis, metabolism and function. The analysis of the APP promoter revealed its similarity with those of housekeeping genes by the presence of a GC-rich region around the transcription start site and the lack of a TATA box. Gene transfer experiments showed this GC-rich region to contain overlapping binding sites for different transcription factors whose binding is mutually excluded. An imbalance between these factors may cause APP overexpression and predispose to AD pathology. Another putative risk factor for AD is regulation of splicing of exon 7 in APP mRNA's which changes in brain during aging. This is relevant for APP processing since exon 7 codes for a Kunitz protease inhibitory domain. Investigation of further splicing adjacent to the beta/A4 exons 16 and 17 which might also interfere with APP processing led to the identification of the leukocyte-derived (L-APP) splice forms which lack exon 15. In brain this splicing occurs in activated astrocytes and microglia. The localization of APP at synaptic sites in brain suggests that APP regulation and expression are critical determinants of a potential and early impairment of central synapses. This may be the case during pathological evolution of AD and DS when beta/A4 derived from synaptic APP is converted to beta/A4 amyloid by radical generation.

A novel zinc(II) binding site modulates the function of the beta A4 amyloid protein precursor of Alzheimer's disease.

Abnormalities of zinc metabolism occur in Alzheimer's disease (AD), a condition where pathological catabolism of the amyloid protein precursor (APP) causes cerebral beta A4 amyloidosis. An association between zinc and APP metabolism was sought by studying the binding of 65Zn2+ to APP. 65Zn2+ bound in a rapid, saturable, and specific manner (KD = 764 nM). A novel zinc binding motif, strongly conserved between members of the APP family, was located between the cysteine-rich and negatively charged domains of the protein. Zinc increased binding of APP to heparin and has been shown to potentiate the inhibition of coagulation factor XIa by an APP isoform containing a Kunitz-type inhibitory domain (Komiyama, Y., Murakami, T., Egawa, H., Okubo, S., Yasunaga, K., and Murata, K. (1992) Thromb. Res. 66, 397-408) situated near the zinc binding region. Zinc is a factor that modulates the functional properties of the substrate for beta A4 amyloidogenesis.

Overlapping binding sites of two different transcription factors in the promoter of the human gene for the Alzheimer amyloid precursor protein.

A four- to fivefold overexpression of the gene for the Alzheimer amyloid precursor protein (APP) in individuals with Down's syndrome (DS) appears to be responsible for the fifty year earlier onset of Alzheimer's disease pathology in DS compared to the normal population. Elucidation of the mechanisms regulating the expression of the human APP gene might therefore be an important step forward in understanding the processes leading to Alzheimer's disease. Recently, an activating DNA fragment proximal to the transcriptional start site of the APP gene was identified, composed of two GC-elements, A and C, both required for full transcriptional activation (1). Here I present evidence that the transcription factor Sp1 can bind to element A and that another specific complex, called C2A, can be observed, which covers a region overlapping with the Sp1 binding site on the APP promoter. Gene transfer experiments with a truncated version of the APP promoter containing mutated binding sites for the factors mentioned above support that at least two different and independent regulatory pathways for APP gene expression might exist. An imbalance between these pathways is proposed to be a putative risk factor for the development of Alzheimer's disease.

The expression of the amyloid precursor protein (APP) is regulated by two GC-elements in the promoter.

The structure of the promoter of the human APP gene resembles that of housekeeping genes, with the presence of a GC-rich region and the lack of a canonical TATA box. Since analysis of the expression of the APP gene, especially at the transcriptional level, might reveal factors or elements, which influence amyloid formation in Alzheimer's disease, a 5' deletion analysis of the APP promoter was performed, leading to the identification of an activating DNA fragment (Ac), acting also on a heterologous promoter. DNaseI-footprint analysis revealed three protected regions on the Ac fragment. Further gene transfer experiments showed, that at least two elements, designated A and C, confer transcriptional activity in HeLa cells. Whereas the proximal element A is a 19bp long GC-rich DNA sequence, the distal element C is a GC-palindrome with the sequence 5'GCGGCGCCGC.

Reduction of N-myc expression by antisense RNA is amplified by interferon: possible involvement of the 2-5A system.

Expression of myc-box genes can be reduced by Interferon (c-myc in Daudi cells) or Retinoic acid (N-myc in neuroblastoma cells). Interferon did not reduce N-myc expression in neuroblastoma cells. However, after transfection of the human neuroblastoma cell line LS with a vector, providing the Cadmium inducible expression of an antisense N-myc transcript, drastic reduction of N-myc RNA was achieved in these cells by incubation with Cadmium and Interferon. Treatment with Cadmium alone resulted in a comparably small reduction of N-myc transcripts in these cells. Interferon alone did not appreciably affect N-myc expression. Reduction of N-myc was accompanied with reduced cell proliferation and morphological differentiation. It is assumed that most of the inhibitory effects observed are mediated by the Interferon inducible 2-5A system.

[The role of interferons in neuroblastoma. 1: Antiproliferative effects]. / Die Rolle der Interferone beim Neuroblastom. Teil 1: Antiproliferative Effekte.

Antiproliferative effects of interferon alpha, beta and gamma were investigated on several human neuroblastoma cell lines using the soft agar colony forming assay and the MTT-test. Investigations were carried out in order to prove whether there is any relationship between antiproliferative effects, inhibition of N-myc expression and the 2-5A system. Growth of neuroblastoma cells was inhibited by all three kinds of interferons in a concentration-dependent manner, however, rather high concentrations were necessary in some cell lines. Expression of N-myc oncogen was not inhibited by interferon-beta and no relationship between antiproliferative effects and the 2-5A system was observed. A vector containing a small N-myc fragment in antisense direction was constructed and transferred into the interferon insensitive human neuroblastoma cell line LS. After transformation, LS cells became sensitive to interferon beta: Proliferation as well as N-myc expression were inhibited and these processes are most probably associated with activation of the 2-5A system.

Tumorigenicity of SEWA murine cells correlates with degree of c-myc amplification.

Previous studies have shown that cells of the SEWA mouse tumor contain amplified copies of the proto-oncogene c-myc in the aberrant chromosomal structures of double minutes (DMs), homogeneously staining regions (HSRs) and C-bandless chromosomes (CMs). DMs, and to a lesser degree CMs, tend to disappear from the cells grown in vitro and again reappear after transfer back in vivo, as if DNA amplification confers a growth advantage upon the tumor cells. We have now isolated five in vitro clones that exhibit different degrees of c-myc amplification. When we inoculated cells of the different clones into compatible hosts, we found that there was a positive correlation between degree of c-myc amplification, level of c-myc RNA, and tumorigenicity. Our results lend further support to the idea that gene amplification contributes to the higher malignant phenotype, and to progression of tumors.

Application of an immunoprecipitation procedure to the study of SV40 tumor antigen interaction with mouse genomic DNA sequences.

Simian Virus 40 (SV40) large T antigen is a DNA binding protein with high affinity for segments of the viral genome. To find out whether T antigen also binds to sequences of genomic cellular DNA we mixed T antigen and SAU 3 A restricted mouse DNA under stringent DNA binding conditions. Resulting protein-DNA complexes were immunoprecipitated using T antigen specific monoclonal or polyclonal antibodies. The DNA fragments in the immunoprecipitates were cloned in plasmid vectors. Four plasmid clones were selected for a detailed investigation of the inserted mouse DNA fragments. Nucleotide sequencing and DNase I footprint experiments showed that T antigen binds to sites in these fragments consisting of two tandemly oriented G(A)AGGC pentamers separated by AT rich spacers of different lengths. The cellular binding sites are very similar in their architecture to the SV40-DNA binding site I. The isolated cellular DNA fragments with T antigen binding sites occur only once or a few times in the mouse genome. Our data help to further define the structure of T antigen's DNA binding sites. The genetic functions of the isolated cellular DNA elements are not known.