The pectoral anatomy of selected Ostariophysi. I. The Characiniformes.

The muscles and bones of the pectoral fin of Serrasalmus nattereri, the piranha, resemble those of generalized, lower teleosts with specializations related to a body shape adapted for high-speed carnivory; the pectoral fins being highly mobile with strong ligaments to the rays. The presence of two occipital nerves appears primitive, while the emergence of the subclavian artery within the branchial cavity, as in Gasteropelecus sternicla, appears specialized. The muscles and bones of the latter fish, a fresh-water flying fish, are specialized for self-propelled, aerial flight in the fusion of the right and left girdles greatly expanded for insertions of complex appendicular (flight) muscles, and in the consolidation of the rays and radials into one functional unit moving vertically in flight through contraction of vertical, massive ventral flight muscles. The bony pectoral anatomy of Electrophorus electricus, the electric eel, is specialized in having a mobile joint between the primary girdle and the cleithrum, the former being suspended vertically from the cleithrum by ligaments. The proximal radials and rays are very numerous and vertically aligned. The cleithrum is shaped to accommodate the extensive sternohyoid and pharyngocleithral muscles. The sheet-like appendicular muscles extend beyond the special joint and control its movement. The deeper muscles do not cross this joint. The arterial system is specialized in lacking a deep brachial artery.     

The birth of immunology. III. The fate of the phagocytosis theory.

During the period of 1895-1910, immunology was preoccupied with defining the cellular (Elie Metchnikoff's phagocytosis theory) as opposed to the humoral basis of bactericidal defense. Although initial discovery of immunopathologic phenomena had been made (e.g., relating to transplantation, autoimmunity, allergy), focus on microbicidal therapy and diagnosis of infectious diseases remained the major stimuli of inquiry. The debate concerning the relative roles of phagocytes, complement, amboceptors (sensibilizing factors, antibody, antitoxins), various lysins (e.g., bacteriolysins, spermatolysins, hemolysins), agglutinins, stimulines, and then Almoth Wright's opsonins reflects the ambiguity of a scientific language being created in an era still struggling with a poorly defined experimental system, for the language, both its vocabulary (newly studied phenomena) and grammar (operational mechanisms) was yet to be codified. The joint award of the Nobel Prize to Metchnikoff and Paul Ehrlich in 1908 for their respective contributions to the "theory of immunity" appeared to proclaim a consensus, but the secret Nobel Committee reports that evaluated Metchnikoff's contributions reveal only a grudging acceptance of his position, and the award was clearly made on the basis of an apparent complementarity between the theoretical views of the humoralists and those elements of the phagocytosis theory that fit the then current discussion of immunity. In this regard, opsonins played an especially important role as both an experimental and conceptual bridge between the competing schools. What was no longer under consideration (and in fact never was explicitly debated) concerned the intellectual foundation of Metchnikoff's original concept of immunity as those activities that defined organismal identity, (developed from Metchnikoff's research in developmental biology) and which regarded host defense mechanisms as only subordinate to this primary function. Immunology in the first half of the 20th century pursued issues pertinent to chemically characterizing immune specificity and only later returned to the Metchnikovian question of how the immune identity was established. This latter venture has achieved molecular sophistication, but even such a formulation may be an inadequate answer to the Metchnikovian postulate. The theoretical discussion between cellularists and humoralists continues in new guises, for the essential debate remains unresolved.     

The low-temperature mechenical relaxation of elastin. I. The dry protein.

The low-temperature relaxation of native ox Ligamentum nuchae elastin and of two purified elastin samples has been investigated in the dry state by means of the Rheovibron DDV II viscoelastometer, at the fixed frequencies of 3.5, 11, 35, and 110 Hz. Besides the glass transition at about 200°C, a relatively strong secondary loss-tangent peak, whose activation energy is about 13 kcal/mol, is found for all samples below room temperature. The peak maximum is at ?71°C for the 3.5-Hz frequency. On the basis of its location, intensity, and width, it is attributed to a main-chain relaxation of the pure protein. When suitable reduced variables are used, the loss-tangent-temperature curves obtained at different frequencies can be satisfactorily superimposed to give a master curve. Comparison of the data with the prediction of a semiempirical viscoelastic model can also be considered satisfactory.     

The chemical composition of wool. XV. The cell membrane couplex.

The cell membrane complex of wool has been examined by electron microscopy of stained cross sections after immersion of the wool in formic acid. The cell membrane complex of the cortex is considerably modified by the treatment, but that of the cuticle appears unchanged. Resistant membranes from cuticle cells, cortical cells and wool have been prepared by treatment with performic acid-ammonia. Amino acid analyses show that the resistant membranes from the cuticle contain citrulline but those from cortical cells do not. It is concluded that the cell membrane complex of the cuticle differs from that of the cortex. Because of the high lysine content of the resistant membranes, their resistance to chemical attack, the hydrophobicity of epicuticle and the observation of a small amount of epsilon-(gamma-glutamyl)lysine, it is postulated that the resistant membranes may contain an appreciable amount of epsilon-(gamma-glutamyl)lysine cross links.     

The organic codes. The basic mechanism of macroevolution.

The origin of the genetic code coincided with the origin of life, while the human codes of cultural evolution emerged almost four billion years later. Modern biology does not recognize any other organic code in nature, and is bound therefore to conclude that the whole of cellular evolution consisted of informational changes. Semantic transformations, natural conventions and biological meaning are things that officially do not exist in the organic world, and play no part in our reconstruction of development and evolution. And yet the properties of organic codes are beginning to emerge in various biological processes. Here it is shown that splicing, signal transduction and pattern formation can be accounted for precisely by the existence of organic codes. It is also shown that those processes were instrumental in bringing about major changes in the history of life, and it is concluded that every main step of macroevolution corresponded to the origin of a new organic code.