Päivi J. Koskinen

Angiotensin I-converting enzyme inhibitory properties of whey protein digests: concentration and characterization of active peptides.

The aim of this study was to identify whey-derived peptides with angiotensin I-converting enzyme (ACE) inhibitory activity. The bovine whey proteins alpha-lactalbumin and beta-lactoglobulin were hydrolysed with pepsin, trypsin, chymotrypsin, pancreatin, elastase or carboxypeptidase alone and in combination. The total hydrolysates were fractionated in a two step ultrafiltration process, first with a 30 kDa membrane and then with a 1 kDa membrane. Inhibition of ACE was analysed spectrophotometrically. The peptides were isolated by chromatography and identified by mass and sequencing analysis. The most potent inhibitory peptides were synthesized by the 9-fluorenylmethoxycarbonyl solid phase method. Inhibition of ACE was observed after hydrolysis with trypsin alone, and with an enzyme combination containing pepsin, trypsin and chymotrypsin. Whey protein digests gave a 50% inhibition (IC50) of ACE activity at concentration ranges within 345-1733 micrograms/ml. The IC50 values for the 1-30 kDa fractions ranged from 485 to 1134 micrograms/ml and for the < 1 kDa fraction from 109 to 837 mg/ml. Several ACE-inhibitory peptides were isolated from the hydrolysates by reversed-phase chromatography, and the potencies of the purified peptide fractions had IC50 values of 77-1062 microM. The ACE-inhibitory peptides identified were alpha-lactalbumin fractions (50-52), (99-108) and (104-108) and beta-lactoglobulin fractions (22-25), (32-40), (81-83), (94-100), (106-111) and (142-146).

Alternative Forms of Max as Enhancers or Suppressors of Myc-Ras Cotransformation

Max is a basic-helix-loop-helix-Ieucine zipper protein capable of forming sequence-specific DNA binding complexes with Myc proteins. An alternatively spliced messenger RNA has been identified that encodes a form of Max truncated at the COOH-terminus. This ΔMax protein retained the ability to bind to the CACGTG motif in a complex with c-Myc but lacks the nuclear localization signal and the putative regulatory domain of Max. When tested in a myc-ras cotransformation assay in rat embryo fibroblasts, Max suppressed, whereas ΔMax enhanced, transformation. Thus, the maxgene may encode both a negative and a positive regulator of c-Myc function.

Immediate early gene responses of NIH 3T3 fibroblasts and NMuMG epithelial cells to TGF beta-1.

Transforming growth factor beta has a wide range of physiological effects on cell growth and metabolism. We have previously reported on the rapid induction of jun transcription factors in TGF beta-treated cells. Here we show that the early genomic response to TGF beta-1 includes activation of a broad spectrum of serum-inducible genes both in NIH 3T3 fibroblasts and in NMuMG epithelial cells, which are growth-stimulated and growth-inhibited by TGF beta, respectively. Of particular interest is the presence of a putative nuclear DNA-binding receptor (N10) and zinc finger transcription factors (Krox 20 and Krox 24) among the TGF beta-induced genes. In addition to the stimulatory effects of TGF beta, expression of a few genes including c-myc is decreased in both types of cells. In cells transformed by neu or ras oncogenes the immediate early mRNA responses to TGF beta are deregulated. Our results suggest that certain transcription factors are required for both positive and negative regulation of cell proliferation by TGF beta, and that their relative concentrations may determine the subsequent cellular responses.

A chimeric EGFR/neu receptor in functional analysis of the neu oncoprotein.

As the factor binding to the neu protein has been unknown, it has not been possible to confirm experimentally the proposed growth-factor receptor like functions of the neu protein. To approach this problem we constructed a recombinant receptor which enabled ligand regulation of the neu tyrosine kinase. The hybrid receptor consisted of the extracellular ligand binding, transmembrane and protein kinase C-substrate domains joined to the intracellular tyrosine kinase and carboxyl-terminal domains of the neu protein. Several properties of NIH3T3 cells carrying this construct were tested. We obtained the first experimental evidence that the neu proto-oncogene has mitogenic and transforming activities only in the presence of a ligand stimulating its tyrosine kinase activity. Various cellular and molecular biological parameters indicated that the chimeric receptor behaved very similarly to the EGFR. Also, this chimeric receptor has allowed us to compare the constitutive oncogenic and the ligand-activated non-oncogenic activities of the neu tyrosine kinase. In the future we plan to focus on characterization of possible differences between EGFR and neu signalling in more differentiated cellular backgrounds.

myc Amplification: regulation of Myc function

The myc oncogenes have been implicated in the control of cell proliferation in both normal and neoplastic cells. There is increasing evidence that Myc proteins function as transcriptional regulators of other genes apparently involved in the control of cell proliferation. The effects of Myc on both gene expression and cell growth are differentially regulated by the recently described Max and delta Max proteins that can either cooperate or compete with Myc for sequence-specific DNA binding.

A chimeric EGFR/neu receptor in studies of neu function

Soon after the characterization of the neu oncogene by Weinberg and colleagues [1, 2], the discovery of its amplification in breast cancer by Slamon and others [3, 4, 5, 6] created an intense interest in its cellular function. Defining the role of neu in cellular transformation became a high-priority task in many laboratories around the world.