Hugh Davis's Commonplace Book: A New Source of Seventeenth-Century Song

Among the Stafford family papers in Staffordshire Record Office is a small bundle of miscellaneous musical items which is as yet uncatalogued. There are incomplete sets of Richard Dering's Cantiones Sacrae (1617) and Cantica Sacra (1618) for five and six voices respectively, Giovanni Croce's Musica Sacra: To Sixe Voices (1611 edition), Agostino Agazzari's Madrigali a Cinque Voci (1602), George Kirbye's First Set of English Madrigalls (1597), and Thomas Watson's Italian Madrigalls Englished (1590), as well as the Abbé Duval's Principes de la musique pratique par demandes et par réponses (1764). The only manuscript item in the collection is a commonplace book that appears to have been compiled over a number of years by a certain Hugh Davis. Its varied contents range from songs, catches, poems, and Latin orations written in the early 1650s, to folk remedies for various ailments, extracts from Charles Butler's The Principles of Musik in Singing and Setting (1636), and a verbatim copy of James II's first Declaration of Indulgence of 4 April 1687. Although the first ten pieces have been torn out and those that remain are roughly and at times inaccurately notated, the manuscript is of interest in that it provides a rare insight into the musical and literary tastes of an undergraduate in mid-seventeenth-century Oxford, and preserves not only a number of hitherto unrecorded songs but also new sources of acknowledged works by such figures as Nicholas Lanier, John Wilson, Thomas Holmes and the Lawes brothers.

The spindle pole body of Schizosaccharomyces pombe enters and leaves the nuclear envelope as the cell cycle proceeds.

The cycle of spindle pole body (SPB) duplication, differentiation, and segregation in Schizosaccharomyces pombe is different from that in some other yeasts. Like the centrosome of vertebrate cells, the SPB of S. pombe spends most of interphase in the cytoplasm, immediately next to the nuclear envelope. Some gamma-tubulin is localized on the SPB, suggesting that it plays a role in the organization of interphase microtubules (MTs), and serial sections demonstrate that some interphase MTs end on or very near to the SPB. gamma-Tubulin is also found on osmiophilic material that lies near the inner surface of the nuclear envelope, immediately adjacent to the SPB, even though there are no MTs in the interphase nucleus. Apparently, the MT initiation activities of gamma-tubulin in S. pombe are regulated. The SPB duplicates in the cytoplasm during late G2 phase, and the two resulting structures are connected by a darkly staining bridge until the mitotic spindle forms. As the cell enters mitosis, the nuclear envelope invaginates beside the SPB, forming a pocket of cytoplasm that accumulates dark amorphous material. The nuclear envelope then opens to form a fenestra, and the duplicated SPB settles into it. Each part of the SPB initiates intranuclear MTs, and then the two structures separate to lie in distinct fenestrae as a bipolar spindle forms. Through metaphase, the SPBs remain in their fenestrae, bound to the polar ends of spindle MTs; at about this time, a small bundle of cytoplasmic MTs forms in association with each SPB. These MTs are situated with one end near to, but not on, the SPBs, and they project into the cytoplasm at an orientation that is oblique to the simple axis. As anaphase proceeds, the nuclear fenestrae close, and the SPBs are extruded back into the cytoplasm. These observations define new fields of enquiry about the control of SPB duplication and the dynamics of the nuclear envelope.

Changes in intracellular pH caused by high K in normal and acidified frog muscle. Relation to metabolic changes.

We examined the effect of depolarization on intracellular pH (pHi) of normal (pHi approximately 7.37) and acidified (pHi 5.90-6.70) frog semitendinosus muscle using microelectrodes. A small bundle was superfused with a Na(+)-free buffered solution (10 mM HEPES, 100% O2, pH 7.35) containing either 2.5 or 25 mM K+. An NH4Cl prepulse was used to lower pHi. At normal pHi, depolarization usually produced a slight (0.04) alkalinization, followed by a fall in pHi of approximately 0.2. In contrast, in all 25 acidified bundles pHi rose by 0.1-0.7. The rise was greater the lower the initial pHi. It could be imitated by caffeine and blocked by tetracaine and thus was, most likely, initiated by release of calcium. We ascribed the alkalinization to hydrolysis of phosphocreatine (PCr); 2,4-dinitrofluorobenzene abolished it. Biochemical analysis on fibers at the peak of alkalinization showed PCr to be reduced by one-half, while PCr in normal fibers that had been depolarized for the same period (4-6 min) showed no change. We postulated that low pHi slows glycolysis with its associated ATP formation by reducing glycogenolysis and particularly by reducing conversion of fructose-6-phosphate to fructose-1,6-diphosphate through inhibition of phosphofructokinase (PFK), an enzyme which is known to be highly pH sensitive. Thus PCr hydrolysis would be required to replace much of the hydrolyzed ATP. This postulated effect on PFK is in agreement with the finding that glucose-6-phosphate (in near-equilibrium with fructose-6-phosphate) was increased nearly fivefold in the depolarized acid fibers, but not in the depolarized normal fibers. However, fructose-1,6-diphosphate also increased significantly; 3-phosphoglycerate was not affected. This suggests an additional acid-induced bottleneck between the latter two substrates. We measured the intrinsic buffering power, beta, of frog semitendinosus muscle with small pulses of NH4Cl. It was found to vary with pHi according to beta = 144.6 - 17.2 (pHi).

Neuronal motility: the ultrastructure of veils and microspikes correlates with their motile activities

We have documented the ultrastructural characteristics that correlate with protrusion, adhesion and retraction of neuronal veils and microspikes, by filming individual neurons of the chick ciliary ganglion and examining the same cells with high-voltage electron microscopy. We find that new veils invariably contain only a cortical meshwork of filaments and are devoid of microtubules, groups of vesicles and other organelles. At sites of recent veil retraction a cortical meshwork on the substratum side underlies a filament-free space containing vesicle clusters and a complexly folded upper membrane. Areas without veil activity are smooth-surfaced and contain a three-dimensional lattice of filaments. We discuss the implications of these observations for the mechanisms of surface recruitment and retrieval during motile activity. We also find that the ultrastructure of moving and attached extensions of the cell surface differs dramatically. Unattached microspikes and actively extending veils have an open, criss-cross array of filaments, whereas attached microspikes contain more aligned filaments, which extend as a small bundle into the growth cone. These results suggest that cell surface protrusion is mediated by meshworks of loosely packed filaments. More compact bundles of filaments are probably generated only at adhesion points.

Nonrandom chromosome segregation in Neocurtilla (Gryllotalpa) hexadactyla: an ultrastructural study.

During meiosis I in males of the mole cricket Neocurtilla (Gryllotalpa) hexadactyla, the univalent X1 chromosome and the heteromorphic X2Y chromosome pair segregate nonrandomly; the X1 and X2 chromosomes move to the same pole in anaphase. By means of ultrastructural analysis of serial sections of cells in several stages of meiosis I, metaphase of meiosis II, and mitosis, we found that the kinetochore region of two of the three nonrandomly segregating chromosomes differ from autosomal kinetochores only during meiosis I. The distinction is most pronounced at metaphase I when massive aggregates of electron-dense substance mark the kinetochores of X1 and Y chromosomes. The lateral position of the kinetochores of X1 and Y chromosomes and the association of these chromosomes with microtubules running toward both poles are also characteristic of meiosis I and further distinguish X1 and Y from the autosomes. Nonrandomly segregating chromosomes are typically positioned within the spindle so that the kinetochoric sides of the X2Y pair and the X1 chromosome are both turned toward the same interpolar spindle axis. This spatial relationship may be a result of a linkage of X1 and Y chromosomes lying in opposite half spindles via a small bundle of microtubules that runs between their unusual kinetochores. Thus, nonrandom segregation in Neocurtilla hexadactyla involves a unique modification at the kinetochores of particular chromosomes, which presumably affects the manner in which these chromosomes are integrated within the spindle.

The Threshold for Potassium-Induced Contractures of Frog Skeletal Muscle. Potentiation of Potassium-Induced Contractures by Preexposure to Subthreshold Potassium Concentrations

A brief exposure (about 10–30 s) of a frog's toe muscle or a small bundle of fibers from the semi-tendinosus muscle to just subthreshold potassium concentrations potentiated contractures subsequently produced by exposing the muscles to a potassium concentration slightly above the threshold. The contractures thus potentiated had greater maximum tensions, and greater rates of tension development and relaxation than control contractures elicited by the same final potassium concentration. The resistance to stretch (R.T.S.) in the first few seconds of the potentiated contractures was about twice that of control contractures. Maximum potentiation occurred with preexposures of about 30 s; longer preexposures led to a decrease of potentiation and eventually to a depression of the contracture. The potentiation was not immediately abolished when the muscle was reexposed to Ringer solution but persisted for 2 min or longer (the 'washout effect'). It was concluded that exposing a muscle to low subcontracture threshold concentrations of potassium for a few seconds primes the intracellular contractile apparatus, probably by causing an increased sarcoplasmic concentration of Ca2+ ions, resulting in a potentiation of subsequently induced submaximal potassium contractures. The increase in metabolism (or 'Solandt effect') seen under these conditions is temporally related to the decline and eventual loss of the potentiation and is probably a reflection of active processes involved in reducing the sarcoplasmic concentration of Ca2+ ions.

THE GEOMETRY OF PERIPHERAL MYELIN SHEATHS DURING THEIR FORMATION AND GROWTH IN RAT SCIATIC NERVES

In rat sciatic nerves, a small bundle of fibers was identified in which myelin sheaths were absent at birth, appeared within 3 days, and grew rapidly for 2 wk. During this interval, nerves were removed from littermates and were sectioned serially in the transverse plane. Alternating sets of thin and thick sections were used to prepare electron micrograph montages in which single myelinating axons could be identified and traced distally. During the formation of the first spiral turn, the mesaxon's length and configuration varied when it was studied at different levels in the same Schwann cell. The position of the mesaxon's termination shifted while its origin, at the Schwann cell surface, remained relatively constant. Along myelin internodes composed of two to six spiral turns, there were many variations in the number of lamellae and their contour. Near the mesaxon's origin, longitudinal strips of cytoplasm separated the myelin layers. Thicker sheaths were larger in circumference, more circular in transverse sections, and more uniform at different levels. Irregularities were confined to the paranodal region, and separation of lamellae by cytoplasm occurred at Schmidt-Lantermann clefts. Approximate dimensions of the bundle, its largest fibers, and their myelin sheaths were measured and calculated. The myelin membrane's transverse length and area increased exponentially with time; the growth rate increased rapidly during the formation of the first four to six spiral layers and remained relatively constant during the subsequent enlargement of the compact sheath.