Origins of metabolic profiling.

Quantitative metabolic profiling originated as a 10-year project carried out between 1968 and 1978 in California. It was hypothesized and then demonstrated that quantitative analysis of a large number of metabolites - selected by analytical convenience and evaluated by computerized pattern recognition - could serve as a useful method for the quantitative measurement of human health. Using chromatographic and mass spectrometric methods to measure between 50 and 200 metabolites in more than 15,000 human specimens, statistically significant and diagnostically useful profiles for several human diseases and for other systematic variables including age, diet, fasting, sex, and other variables were demonstrated. It was also shown that genetically distinct metabolic profiles for each individual are present in both newborn infants and adults. In the course of this work, the many practical and conceptual problems involved in sampling, analysis, evaluation of results, and medical use of quantitative metabolic profiling were considered and, for the most part, solved. This article is an account of that research project.

Use of Merrifield solid phase peptide synthesis in investigations of biological deamidation of peptides and proteins.

Merrifield solid phase peptide synthesis has been the principle research procedure used in the study of the chemistry and biological use of deamidation of asparaginyl and glutaminyl residues in peptides and proteins during the past 40 years. During the initial years of investigation, it permitted the qualitative demonstration that primary, secondary, and tertiary structure-determined deamidation half-times vary over a wide range under biological conditions and the discovery of two biological systems in which deamidations serve as molecular clocks. More recently, it has made possible such a thorough quantitative understanding of the structural dependence of deamidation that the deamidation rates of asparaginyl residues in proteins can be predicted from protein three-dimensional structures with a high degree of reliability. This, in turn, has led to the discovery that amide residues serve as molecular clocks in many biological systems and the demonstration of additional examples. In these investigations, Professor R. B. Merrifield contributed his techniques, time, and laboratory resources, both in personally teaching his methods to the principle investigators and in making available his laboratory in which more than 900 peptides were synthesized for this work.

Measurement of deamidation of intact proteins by isotopic envelope and mass defect with ion cyclotron resonance Fourier transform mass spectrometry.

After synthesis and folding, proteins undergo many post-synthetic modifications, including cleavage, oxidation, glycosylation, methylation, racemization, phosphorylation, and deamidation. Of these modifications, non-enymatic deamidation is the most prevalent. Each asparaginyl and glutaminyl residue in a protein is a miniature molecular clock that deamidates with a genetically determined half-time. These half-times vary from a few hours to more than a century, depending on a primary, secondary, tertiary, and quaternary structure near the amide residue. It has been suggested that these clocks regulate many biological processes. A few such processes have been discovered. These discoveries have been difficult because deamidation is inconvenient to measure. While most post-synthetic changes are easily measured by mass spectrometry, deamidation increases molecular mass by only one nominal Dalton, so the deamidated isotopic envelope overlaps the undeamidated isotopic envelope. While peptide deamidation rate determination through deconvolution of these envelopes has been accomplished for several hundred peptides, deconvolution becomes more difficult as the molecular weight increases. In high-resolution mass spectrometers, this deconvolution is possible for larger molecules and an alternative method based on the 19 mDa mass defect between the deamidated envelope and the isotopic envelope of protein fragments can also be utilized. We herein report a comparison of the envelope deconvolution and the mass defect methods for measurement of deamidation in human eye lens crystallins, with special emphasis on betaB2 crystallin and gammaS crystallin. Measurement of extent of deamidation of betaB2 crystallin in a 7 Tesla ion cyclotron resonance Fourier transform mass spectrometer is found to be accurate to a relative standard deviation in a single measurement of about 4% for each method. The envelope deconvolution method is further illustrated by detection of deamidation in intact gammaS crystallin, a 20 904 Da protein, and discovery of the principal gammaS deamidation site.

Quantitative measurement of young human eye lens crystallins by direct injection Fourier transform ion cyclotron resonance mass spectrometry.

PURPOSE: Human eye lenses at birth are primarily constructed of 12 distinct crystallins and two truncated crystallins. The molecular weights of these 14 proteins vary between about 20,000 and 30,000 Da. The relative amounts of these molecules and their post-synthetic changes with age are of substantial interest in the study of lens biochemistry and lens pathology. Fourier transform mass spectrometry of unfractionated lens homogenates now permits precise quantitative measurement of the relative amounts of lens crystallins. We report herein the measurement of the 14 crystallins in 10 pairs of lenses from humans between the ages of 2 and 300 days. METHODS: Eye lenses were obtained from human donors of various ages in the first year of life. These lenses were homogenized in 0.02 M phosphate buffer at pH 7.0 with 0.001 M EDTA, desalted by washing over a 3,000 Da filter, and injected directly into the nanospray source of a hybrid Fourier transform ion cyclotron resonance mass spectrometer, Qq-FT(ICR)MS, equipped with a 12 Tesla magnet. The crystallins were quantitatively ionized and mass analyzed in the ICR cell of the mass spectrometer. The detected signals of all of the isotopic and charge state species for each crystallin were normalized and summed to determine the protein quantities. RESULTS: The relative amounts of the 14 crystallins are found to be quite similar from individual to individual at birth. These amounts are in integer ratios to one another that suggest important structural relations within the lens. In two cases, the relative amounts of alphaA- and betaB2-crystallin change proportionally to the logarithm of age during the first year, with alphaA- decreasing and betaB2-crystallin increasing. The changes in alphaA- and betaB2-crystallin are mutually offsetting, with alphaA-crystallin decreasing from 30% to 18% and betaB2-increasing from 12% to 24%. CONCLUSIONS: These observations suggest that the human eye lens at birth is constructed of crystallins in which the numbers of crystallin molecules have regular integral relationships to each other. As the lens develops during the first year, some of these relationships change. While the functional significance of the reciprocal decrease in alphaA- and increase in betaB2-crystallin is not known, betaB2-crystallin may substitute for alphaA-crystallin in the lens structures synthesized during the year after birth. Direct injection FT(ICR)MS of unfractionated lens was found to be an excellent method for the quantitative measurement of lens crystallins.

Quantitative measurement of deamidation in lens betaB2-crystallin and peptides by direct electrospray injection and fragmentation in a Fourier transform mass spectrometer.

PURPOSE: Deamidation of lens crystallins and specific deamidation sites have been suggested to be associated with aging and cataracts. However, these studies have been hindered by the lack of suitable quantitative methods of measurement of protein deamidation. We demonstrate herein a method to quantitatively measure deamidation of proteins and peptides without prior sample preparation or separation in order to directly compare the amidated and deamidated forms. We have tested the hypothesis that the 19 mDa mass defect that distinguishes deamidated peptides and proteins from the ordinary natural isotopic species can be utilized for quantitative measurement of their rate and extent of deamidation. The measurement technique used was ion cyclotron resonance Fourier transform mass spectrometry (FTMS), alone with no prior sample preparation or separation. The amidated and deamidated species were recombinantly expressed human eye lens betaB2-crystallins and the peptides GlyIleAsnAlaGly and GlyAsnAsnAsnGly. FTMS measurements of lens proteins from a 1-month-old human donor were also carried out. METHODS: Wild type and mutant human eye lens betaB2-crystallins with Gln162 replaced by Glu162 were produced in bacteria, and GlyIleAsnAlaGly and GlyAsnAsnAsnGly were synthesized by Merrifield solid-phase peptide synthesis. The peptides were deamidated in pH 7.4, 37.00 degrees C, 0.15 M Tris-HCl aqueous solution for 18 successive time intervals before analysis. Mutant and wildtype betaB2-crystallin solutions at various compositional percentages were mixed and analyzed. The peptides were introduced by electrospray ionization and immediately analyzed in the ion cyclotron resonance (ICR) Fourier transform mass analyzer. Two mass defect analysis procedures were demonstrated for the proteins. In the first, betaB2-crystallin was introduced into the mass spectrometer by electrospray ionization and the +29 isotopic group was selectively introduced into the ICR mass analyzer, where 14 residue and 18 residue laser-induced fragments were separated and the extent of deamidation determined by mass defect analysis. In the second, betaB2-crystallin was introduced into the mass spectrometer by electrospray ionization and the entire sample was fragmented by collision ionization before introduction into the ICR mass analyzer, where 14 residue fragments were separated and the extent of deamidation determined by mass defect analysis. RESULTS: The betaB2-crystallin mass spectra showed a good quantitative dependence upon extent of deamidation. Direct injection by electrospray ionization followed by ion selection and laser fragmentation or by collision fragmentation produced fragments of amidated and deamidated betaB2-crystallin that were appropriate for FTMS quantitative analysis. The two peptides exhibited the expected four deamidation rate curves with acceptable precision. CONCLUSIONS: Mass defect FTMS quantitative analysis of protein deamidation, as reported for the first time herein and illustrated with betaB2-crystallin, should prove quite useful. This procedure omits gel separation, chromatography, enzymatic digestion, derivatization, and other procedures that currently add cost and time while degrading quantitative comparison of the amidated and deamidated forms. Mass defect FTMS is also well suited to quantitative deamidation rate studies of peptides. The substantial potential significance of this technique is evident, as example, for lens crystallins where it makes possible quantitative studies of age and disease-dependent deamidation that have heretofore been very difficult. This technique should allow convenient and reliable identification and quantitative measurement of specific deamidation sites that may play a role in aging and cataracts.

Amide molecular clocks in drosophila proteins: potential regulators of aging and other processes.

After synthesis and folding, peptides and proteins undergo changes in charge and conformation through nonenzymatic deamidation of asparaginyl and glutaminyl residues. Each amide has a specific deamidation rate that is genetically determined by the sequence of residues immediately adjacent in the peptide chain and by secondary, tertiary, and quaternary structure. By means of experimentally verified computations, we have determined the deamidation rates of 49 Drosophila peptides and proteins. These rates demonstrate that deamidation provides molecular clocks that are suitable for the regulation of Drosophila aging, development, and other biochemical processes. We have also determined the rates of deamidation for 17,886 other proteins from a wide variety of organisms. The distribution function of these deamidation rates demonstrates the suitability of amide residues as biomolecular clocks.

Standardized steel shelters for a national shelter program

For a national shelter program, shelters would probably be fabricated in local shops according to standardized designs and in central facilities with asssembly lines. Factory assembly would have the advantage that large stamping machines could permit the use of corrugated galvanized steel. Corrugated steel shelters would require less steel, since corrugation provides additional strenght. The shelters can be located in playgrounds, parks, yards, streets, parking lots of other locations with less than one week of disruption involved in digging the hole, burying the shelter, and hauling away the left over soil. The shelters should be located in open areas to minimize rubble. Shallow burial with earthen berms or concrete encasement may be required in locations with a high water table. The ventilation and chemical and biological air filtration systems for these shelters are currently being obtained on a one-at-a-time import basis from LUWA in Switzerland. The 60 person LUWA-180 units currently cost about $67 per person sheltered on this expensive custom import basis