Nutrigenetics and nutrigenomics hold much promise for providing better nutritional advice to the public generally, genetic subgroups and individuals. Because nutrigenetics and nutrigenomics require a deep understanding of nutrition, genetics and biochemistry and ever new ‘omic’ technologies, it is often difficult, even for educated professionals, to appreciate their relevance to the practice of preventive approaches for optimising health, delaying onset of disease and diminishing its severity. This review discusses (i) the basic concepts, technical terms and technology involved in nutrigenetics and nutrigenomics; (ii) how this emerging knowledge can be applied to optimise health, prevent and treat diseases; (iii) how to read, understand and interpret nutrigenetic and nutrigenomic research results, and (iv) how this knowledge may potentially transform nutrition and dietetic practice, and the implications of such a transformation. This is in effect an up-to-date overview of the various aspects of nutrigenetics and nutrigenomics relevant to health practitioners who are seeking a better understanding of this new frontier in nutrition research and its potential application to dietetic practice.

Complexes of both hIGF-II and hIGF-IIE with a Fab have been crystallized and investigated by X-ray analysis.

Elevated expression of insulin-like growth factor II (IGF-II) is frequently observed in a variety of human malignancies, including breast, colon and liver cancer. As IGF-II can deliver a mitogenic signal through both the type 1 insulin-like growth factor receptor (IGF-IR) and an alternately spliced form of the insulin receptor (IR-A), neutralizing the biological activity of this growth factor directly is an attractive therapeutic option. One method of doing this would be to find antibodies that bind tightly and specifically to the peptide, which could be used as protein therapeutics to lower the peptide levels in vivo and/or to block the peptide from binding to the IGF-IR or IR-A. To address this, Fabs were selected from a phage-display library using a biotinylated precursor form of the growth factor known as IGF-IIE as a target. Fabs were isolated that were specific for the E-­domain C-terminal extension and for mature IGF-II. Four Fabs selected from the library were produced, complexed with IGF-II and set up in crystallization trials. One of the Fab–IGF-II complexes (M64-F02–IGF-II) crystallized readily, yielding crystals that diffracted to 2.2 Å resolution and belonged to space group P212121, with unit-cell parameters a = 50.7, b = 106.9, c = 110.7 Å. There was one molecule of the complete complex in the asymmetric unit. The same Fab was also crystallized with a longer form of the growth factor, IGF-IIE. This complex crystallized in space group P212121, with unit-cell parameters a = 50.7, b = 107, c = 111.5 Å, and also diffracted X-rays to 2.2 Å resolution.

Background

It was hypothesised that colorectal cancer (CRC) could be diagnosed in biopsies by measuring the combined expression of a small set of well known genes. Genes were chosen based on their role in either the breakdown of the extracellular matrix or with changes in cellular metabolism both of which are associated with CRC progression

Findings

Gene expression data derived from quantitative real-time PCR for the solute transporter carriers (SLCs) and the invasion-mediating matrix metalloproteinases (MMPs) were examined using a Linear Descriminant Analysis (LDA). The combination of MMP-7 and SLC5A8 was found to be the most predictive of CRC.

Conclusion

A combinatorial analysis technique is an effective method for both furthering our understanding on the molecular basis of some aspects of CRC, as well as for leveraging well defined cancer-related gene sets to identify cancer. In this instance, the combination of MMP-7 and SLC5A8 were optimal for identifying CRC.

The insulin-like growth factors (insulin-like growth factor I [IGF-I] and IGF-II) exert important effects on growth, development, and differentiation through the IGF-I receptor (IGF-IR) transmembrane tyrosine kinase. The insulin receptor (IR) is structurally related to the IGF-IR, and at high concentrations, the IGFs can also activate the IR, in spite of their generally low affinity for the latter. Two mechanisms that facilitate cross talk between the IGF ligands and the IR at physiological concentrations have been described. The first of these is the existence of an alternatively spliced IR variant that exhibits high affinity for IGF-II as well as for insulin. A second phenomenon is the ability of hybrid receptors comprised of IGF-IR and IR hemireceptors to bind IGFs, but not insulin. To date, however, direct activation of an IR holoreceptor by IGF-I at physiological levels has not been demonstrated. We have now found that IGF-I can function through both splice variants of the IR, in spite of low affinity, to specifically activate IRS-2 to levels similar to those seen with equivalent concentrations of insulin or IGF-II. The specific activation of IRS-2 by IGF-I through the IR does not result in activation of the extracellular signal-regulated kinase pathway but does induce delayed low-level activation of the phosphatidylinositol 3-kinase pathway and biological effects such as enhanced cell viability and protection from apoptosis. These findings suggest that IGF-I can function directly through the IR and that the observed effects of IGF-I on insulin sensitivity may be the result of direct facilitation of insulin action by IGF-I costimulation of the IR in insulin target tissues.