Epidermal growth factor stimulates type-V collagen synthesis in cultured murine palatal shelves

Abstract. The problem studied was whether treatments that reorient vascular differentiation have a similar effect on the polarity of auxin transport. Hypocotyls of Phaseolus vulgaris L. were cut so that a transverse bridge connected the shoot and root directions. Within three days these bridges of tissue regenerated both vessels and sieve tubes along the new orientation, at 90° to the original axis. Experiments involving organ removal, wounds, and hormone application confirm previous suggestions that this differentiation follows the expected flow of the hormone auxin in the direction of the roots. Transport of (³H) indoleacetic acid through sections in which vascular reorientation occurred was polar: it was at least twice as great in the new direction of the roots than in the opposite direction. This new polarity of transport, at right angles to the original axis of the plant, can be readily understood if there is a positive feed-back between the differentiation of tissue polarity and auxin transport.     

BioMetals: a historical and personal perspective

Understanding of BioMetals developed basically from a starting point about 60 years ago to current mechanistic understanding of the biological behavior of many metal ions from protein structural and functional studies. Figure 1 shows a Biochemical Periodic Table, element by element, with requirements, roles and biochemistry of the specific ions indicated. With few exceptions, the biology is of the ions formed and not of the elemental state of each. Early BioMetals efforts defined nutritional growth needs for animals, plants and microbes for inorganic “macro-nutrients” such as magnesium, calcium, potassium, sodium, and phosphate and of “micronutrients” such as copper, iron, manganese and zinc. Surprises came early with regard to microbes, for example the finding that Escherichia coli (then and now the standard microbial model) grows happily in the apparent total absence of calcium, sodium, and chloride, which are certainly major animal nutrients. Some elements such as mercury and arsenic are never required by living cells, but are always toxic, often at very low levels. Therefore, the division into nutrient elements and toxic elements came soon. For most inorganic nutrients, excessive amounts can be toxic as well, for example for copper and iron.     

Estimation of the abrasive wear coefficient in Lillehei-Kaster cardiac valve prostheses

An approximate hemodynamic theory, which predicts the opening dynamics of the Lillehei-Kaster heart valve, is used in conjunction with an abrasive wear model to predict the wear process on the shields. The hemodynamic theory predicts markedly different opening dynamics between the mitral and aortic positions and is shown to give excellent correlation with the experimental results of other investigations. The abrasive wear model is also shown to give excellent correlation with the experiments of others when the abrasive wear coefficient is taken as k = 6.4 X 10(-6). The theoretical results of this effort and the experimental data from clinical explants of other investigators is used to predict that occluder dislodgement is unlikely in less than 90 yr for either the mitral or aortic positions (for a mean cardiac output of 3.8 l.min-1 and a mean heart rate of 70 beats min-1).     

Isolation of mitotic apparatus containing vesicles with calcium sequestration activity

We present the first report of isolated mitotic apparatus with vesicular calcium sequestration. Phase-contrast, differential interference contrast and polarized light microscopy as well as transmission and scanning electron microscopic examinations revealed structures comparable to mitotic apparatus in vivo. Numerous membrane-bound vesicles which retained their osmotic activity were present throughout. Microtubules, yolk, ribosomes and condensed chromatin were also present. The protein composition of mitotic apparatus was not dramatically altered by treatment with 0.5% Triton X-100, even though vesicles were destroyed and yolk was extracted. Calcium sequestration was demonstrated with ATP-dependent accumulation of ⁴⁵Ca by mitotic apparatus whose vesicles were left intact. Compared with controls for which no nucleotide was added, accumulation by mitotic apparatus with intact vesicles was enhanced to 184% when it was present. When ATP was supplemented with the divalent ionophore A23187, the calcium retention level was comparable to that of the control to which no nucleotide was added. Finally, the calcium accumulation by mitotic apparatus treated with either of the nonhydrolyzable ATP analogs AMPPCP or AMPPNP resulted in calcium retention levels similar to those of controls. The solubilization of vesicles with Triton X-100 abolished calcium accumulation in the presence or absence of any of the above additives. Resolution of vesicles on sucrose step gradients after ⁴⁵Ca-oxalate loading with ATP or AMPPCP indicates that a specific vesicular fraction sequesters ⁴⁵Ca.     

Partial purification and characterization of neutral proteases in lymph nodes of rats with experimental allergic encephalomyelitis

Two kinds of neutral protease activities in lymph nodes from Lewis rats with acute experimental allergic encephalomyelitis (EAE) have been separated and partially purified and characterized. A soluble enzyme preparation enriched by gel filtration and ion-exchange chromatography hydrolyzes myelin basic protein, polylysine, and other basic proteins with an optimum pH at 6.0–6.5. It is inhibited byp-chloromercuribenzoate, and thus appears to be a mixture of thiol proteases. Another fraction containing proteolytic enzyme activity is strongly bound to the insoluble lymph node residue, and it also hydrolyzes myelin basic protein and histone, but not polylysine. It has a pH optimum above 7.5, is inhibited by phenylmethylsulfonyl fluoride, thus resembling elastase, but does not hydrolyze elastin-Congo red. The insoluble enzyme preparation hydrolyzes basic protein to 4–5 peptides in a pattern on polyacrylamide gels resembling that of the hydrolysis of basic protein by whole lymphocytes; the soluble enzyme mixture produces small fragments not retained on gels. Lymphocytes are a major component of the cells inflitrating the nervous system in experimental allergic encephalomyelitis, and neutral proteases contained in these cells may contribute to the degradation of myelin, especially of the basic protein.     

Kinetic studies on the mechanism of pepsin action.

The linear noncompetitive inhibition of the pepsin-catalyzed hydrolysis of Ac-Phe-Phe-Gly at pH 2.1 by L-Ac-Phe, L-Ac-Phe-NH2, and L-Ac-Phe-OEt has been claimed to substantiate the ordered release of products specified by the amino-enzyme mechanism for pepsin action. According to this interpretation, the binding of inhibitor to free enzyme and the amino-enzyme intermediate (Scheme I) generates the observed inhibition pattern. The proposition is valid only if a simple alternative explanation for the kinetic data, Scheme II, can be disproved. Scheme II attributes the inhibition pattern to the binding of inhibitor to free enzyme and the enzyme-substrate (Michaelis) complex. The experiments reported here have enabled us to distinguish between the two mechanisms. The pepsin-catalyzed hydrolyses of Ac-Phe-Trp, Z-H'IS-Phe-Trp, Z-Gly-His-Phe-Trp, and Z-Ala-His-Phe-Trp at pH 1.8 occur exclusively at the Phe-Trp bond and must yield the same amino-enzyme, E-Trp, if it is implicated. Under these circumstances, Scheme I requires that a plot of 1/kc vs. (I)o for the four substrates and a given noncompetitive inhibitor provide a set of four parallel lines. Scheme II predicts that the four lines generally will not be parallel. L-Ac-Phe, L-Ac-Phe-NH2, L-Ac-Phe-OMe, and D-Ac-Phe act as linear noncompetitive inhibitors for the pepsin-catalyzed hydrolysis of the four Trp-containing substrates. The plot of 1/kc vs. (I)o for each inhibitor results in a set of four nonparallel lines. Therefore Scheme II must be correct and the detection of noncompetitive inhibition accompanying the pepsin-catalyzed hydrolysis of peptides offers no insight into the merits of the amino-enzyme hypothesis.