Cell wall composition and synthesis via Golgi-directed scale formation in the marine eucaryote,Schizochytrium aggregatum,with a note on Thraustochytrium sp.

Summary Cell walls of Schizochytrium aggregatum and Thraustochytrium sp. were mechanically isolated and subjected to chemical analysis. On a dry weight basis the cell walls contain 21–36% carbohydrate and 30–43% protein. The principal sugar (>95%) of the Schizochytrium wall is l-galactose, while the Thraustochytrium cell wall contains l-galactose, d-galactose and xylose with l-galactose predominating. Ultrastructurally the cell walls of both organisms consist of a laminated structure which yields thin, flexible, nearly circular scales (0.5–1.1 in diameter) upon sonic disintegration. Structures presumed to be developing wall scales are found within cisternae of the Golgi apparatus in both organisms. The chemical composition and method of formation of the cell wall in these two protists is distinctly different from that found in the Saprolegniales (Oomycetes), the group with which these organisms have hitherto been aligned.     

MICROTUBULES IN THE FORMATION AND DEVELOPMENT OF THE PRIMARY MESENCHYME IN ARBACIA PUNCTULATA : I. The Distribution of Microtubules

Prior to gastrulation, the microtubules in the presumptive primary mesenchyme cells appear to diverge from points (satellites) in close association with the basal body of the cilium; from here most of the microtubules extend basally down the lateral margins of the cell. As these cells begin their migration into the blastocoel, they lose their cilia and adopt a spherical form. At the center of these newly formed mesenchyme cells is a centriole on which the microtubules directly converge and from which they radiate in all directions. Later these same cells develop slender pseudopodia containing large numbers of microtubules; the pseudopodia come into contact and fuse to form a "cable" of cytoplasm. Microtubules are now distributed parallel to the long axis of the cable and parallel to the stalks which connect the cell bodies of the mesenchyme cells to the cable. Microtubules are no longer connected to the centrioles in the cell bodies. On the basis of these observations we suggest that microtubules are a morphological expression of a framework which opeartes to shape cells. Since at each stage in the developmental sequence microtubules appear to originate (or insert) on different sites in the cytoplasm, the possibility is discussed that these sites may ultimately control the distribution of the microtubules and thus the developmental sequence of form changes.     

The Constitutive, Glucose-Repression-Insensitive Mutation of the Yeast MAL4 Locus Is an Alteration of the MAL43 Gene

Mutations resulting in constitutive production of maltase have been identified at each of the five MAL loci of Saccharomyces yeasts. Here we examine a dominant constitutive, glucose-repression-insensitive allele of the MAL4 locus (MAL4-C). Our results demonstrate that MAL4-C is an alteration in the MAL43 gene, which encodes the positive regulator of the MAL structural genes, and that its product is trans-acting. The MAL43 gene from the MAL4-C strain was cloned and integrated into a series of nonfermenting strains lacking a functional regulatory gene but carrying copies of the maltose permease and maltase structural genes. Expression of the maltase structural gene was both constitutive and insensitive to glucose repression in these transformants. The MAL4-C allele also results in constitutive expression of the unlinked MAL12 gene (encoding maltase) in this strain. In addition, the cloned MAL43 gene was shown to be dominant to the wild-type MAL63 gene. We also show that most of the glucose repression insensitivity of strains carrying the MAL4-C allele results from alteration of MAL43.     

Evolution of nuclear gene families in primates,Copy-number variation in the argininosuccinate synthetase (ASS) pseudogene family and the anonymous DNA sequence,D1S1

Changes in the copy number of nuclear genes provide the raw material for the creation of new gene functions. To better understand the mechanisms for such events, and their physiologic and evolutionary consequences, it is valuable to study a well characterized and closely related group of species such as primates. Fortuitously, most of the powerful molecular techniques and DNA probes developed for research in humans are equally applicable to non-human primates. We review what is known of copy number variation in primates and describe two informative DNA probes: pAS-1, a cDNA probe to the human urea cycle enzyme argininosuccinate synthetase (ASS), and an anonymous DNA probe, D1S1.In additon to the ASS structural locus on human chromosome 9, pAS-1 detects at least 14 dispersed, processed pseudogenes in humans. The number of pseudogene copies appears to be approximately the same in humans, chimpanzees, gorillas, orangutans and baboons; less in marmosets; and least in some rodents. Chimpanzees and gorillas appear to have all of the human pseudogenes though an Xp copy may be missing from gorillas. The Y pseudogene is apparently absent from orangutans and baboons, and, finally, a comparison of humans and chimpanzees revealed that the number of nucleotide substitutions in the Y chromosome pseudogenes is approximately 1 per 100.D1S1 maps to human chromosome 3 but also detects a high homology copy on chromosome 1. Chimpanzees, gorillas and orangutans all appear to have only the chromosome 3 homolog suggesting that this is the ancestral sequence and that the duplication occurred after separation of humans and the great apes.Both the ASS pseudogene family and the D1S1 system provide valuable information on the evolution of nuclear gene families in primates.     

Specific asparagine-linked oligosaccharides are not required for certain neuron-neuron and neuron-Schwann cell interactions

To determine whether specific asparagine-linked (N-linked) oligosaccharides present in cell surface glycoproteins are required for cell-cell interactions within the peripheral nervous system, we have used castanospermine to inhibit maturation of N-linked sugars in cell cultures of neurons or neurons plus Schwann cells. Maximally 10-15% of the N-linked oligosaccharides on neuronal proteins have normal structure when cells are cultured in the presence of 250 micrograms/ml castanospermine; the remaining oligosaccharides are present as immature carbohydrate chains not normally found in these glycoproteins. Although cultures were treated for 2 wk with castanospermine, cells always remained viable and appeared healthy. We have analyzed several biological responses of embryonic dorsal root ganglion neurons, with or without added purified populations of Schwann cells, in the presence of castanospermine. We have observed that a normal complement of mature, N-linked sugars are not required for neurite outgrowth, neuron-Schwann cell adhesion, neuron-induced Schwann cell proliferation, or ensheathment of neurites by Schwann cells. Treatment of neuronal cultures with castanospermine increases the propensity of neurites to fasciculate. Extracellular matrix deposition by Schwann cells and myelination of neurons by Schwann cells are greatly diminished in the presence of castanospermine as assayed by electron microscopy and immunocytochemistry, suggesting that specific N-linked oligosaccharides are required for the expression of these cellular functions.     

Preservation of mouse embryos by two-step freezing

Eight-cell mouse embryos in 1.5 M DMSO were preserved in LN₂ by a two-step procedure. Fifteen minutes exposure at ?20 °C protected the embryos against damage during rapid cooling to -196 °C and during rapid warming and rapid dilution. Since survival was poor on slow warming it is suggested that the method permits the formation of some intracellular ice.     

The ultrastructure of process formation following treatment with db-cAMP of a Chinese hamster ovary X Chinese hamster brain cell hybrid

Scanning (SEM) and transmission (TEM) electron microscopy studies were performed on a hybrid, resulting from the Sendai-virus fusion of a Chinese hamster ovary (CHO) Glycine A (Gly⁻A) auxotrophic mutant cell [1,2] with a freshly-biopsied suspension of Chinese hamster cerebral cortex cells. In normal growth medium the hybrid differs from the CHO parental cell in displaying a squamous, polygonal, epithelioid appearance with sparse microvilli and ribosome-filled knobs (blebs). Slender filopodia, which sometimes reach a length of 25 μm, extend from interphase cells. Bundles of microfilaments (6 nm diameter) are observed closely associated with the cell membrane and the perinuclear region, arranged more or less in parallel to the glass substrate. The untreated hybrid has a relatively unpatterned arrangement of microtubules and reveals desmosomes at points of cell contact. When treated with N⁶,O²-dibutyryl adenosine 3′:5′-cyclic monophosphoric acid (db-cAMP) plus the Synergist testololactone, the response of the hybrid differs markedly from the fibroblastic habitus assumed by CHO [3, 4, 5]. The hybrid cells become stellate, forming processes or cytoplasmic extensions which radiate from a central, microvillus-covered, rounded, cell body. The arborizing processes number 2–8 per cell and form a contiguous network between cells of a colony. Desmosomes are seen at these points of process-to-cell body junctions. Parallel microtubules, 10 nm filaments, and 6 nm microfilaments, as well as organelles of the unstimulated cytoplasm such as free ribosomes, lipid granules, mitochondria, rough ER, and myelin figures are present in the nerve-like extensions. Knobs disappear completely following cAMP treatment. On removal of the db-cAMP, disappearance of the processes is apparent in 1–2 h so that the cell returns to its original morphology. This reversal is accompanied by ruffling activity at the cell borders. The central, rounded portion of the cell returns to the former flattened state somewhat more slowly. These studies demonstrating a cAMP-induced change in morphology and microtubule arrangement, produced in CHO X brain cell hybrids support the previous proposals that: (1) cAMP action is necessary for organization of cellular microtubules to form a pattern; (2) this pattern is a function of the cellular differentiation state and is determined by genetic or epigenetic factors.     

Apparent Co-Sequestration of Immunoreactive Corticotropin, α-Melanot opin, and γ-Lipotropin in Hypothalamic Granules

Abstract: In the present study, the question of whether immunoreactive α-melanotropin (α-MSH₁), corticotropin (ACTH₁), and β-melanotropin (β-MSH₁) are co-sequestered in hypothalamic granules of adult male rats was addressed. When a 900 ×g supernatant fluid prepared from a hypothalamic homogenate was fractionated on continuous sucrose density gradients under non-equilibrium Conditions, two populations of particles containing α-MSH₁, ACTH₁, or β-MSH₁ Were observed. However, when fractionated under equilibrium conditions, the two populations of particles containing α-MSH₁ ACTH₁, or β-MSH₁ were recovered as a single band. This sedimentation characteristic indicates that the particles containing a given peptide differ in size but are similar in density. In their sedimentation, the small particles containing α-MSH₁, ACTH₁, and β-MSH₁ are indistinguishable from granules containing α-MSH₁, whereas the large particles containing α-MSH₁ (ACTH₁, and β-MSH₁ are indistinguishable from synaptosomes containing α-MSH₁, β-MSH₁ had an apparent molecular weight (M.W.) of about 5,000, which is similar to that of γ-lipotropin. ACTH₁ was comprised of three species of molecules: big (M.W. ≥ 10,000), 5.7K (M.W. ≌ 5,700), and 4.5K (M.W. ≌ 4,500). Big ACTH was the predominant and 5.7K ACTH the minor component of ACTH₁ present in granules as well as in synaptosomes. These results are suggestive that α-MSH, ACTH and its precursors, and γ-lipotropin are co-sequestered in hypothalamic granules.