Kinetics of circadian band development in Neurospora crassa.

The circadian rhythm of Neurospora crassa can be seen as a conidiation rhythm that produces concentric rings of bands (conidiating regions) alternating with interbands (non-conidiating regions) on the surface of an agar medium. To follow quantitatively this rhythm, densitometric analysis, gravimetric procedures, and video microscopy were employed. The circadian behavior of N. crassa is commonly monitored by cultivation in race tubes; in this work we report different growth kinetics during cultivation in conventional Petri dish cultures. Two different growth parameters were measured: total colony mass (true growth rate) and distance (colony radial expansion or hyphal elongation). Determinations of cellular mass revealed a dramatic circadian oscillation with a marked drop in growth rate during new interband formation followed by a sharp increase during the development of a new conidiation band. On the other hand, we found that the radial expansion of the colony previously reported to decrease periodically seemed unaffected by the circadian clock. Densitometric analysis showed no initial difference in the expanding margin of the colony, independent of whether that area was destined to be a band or an interband. The band areas increased rapidly in density for about 15 h whereas the interband areas maintained an equally rapid rate of increase for only 6h. The density of band areas kept increasing slowly for almost 40 h, along with an increase in the amount of conidia. Video microscopy showed the importance of cytoplasmic flow in colony development with continuous forward flow to support hyphal morphogenesis and reverse flow to support an extended period of conidiogenesis. Our results indicate that the circadian system of Neurospora can be expressed at the level of cellular mass formation, not just as the developmental conidiation rhythm.

Apical growth and mitosis are independent processes in Aspergillus nidulans.

It is well established that cytoplasmic microtubules are depolymerized during nuclear division and reassembled as mitotic microtubules. Mounting evidence showing that cytoplasmic microtubules were also involved in apical growth of fungal hyphae posed the question of whether apical growth became disrupted during nuclear division. We conducted simultaneous observations of mitosis (fluorescence microscopy) and apical growth (phase-contrast microscopy) in single hyphae of Aspergillus nidulans to determine if the key parameters of apical growth (elongation rate and Spitzenkörper behavior) were affected during mitosis. To visualize nuclei during mitosis, we used a strain of A. nidulans, SRS27, in which nuclei are labeled with the green-fluorescent protein. To reveal the Spitzenkörper and measure growth with utmost precision, we used computer-enhanced videomicroscopy. Our analysis showed that there is no disruption of apical growth during mitosis. There was no decrease in the rate of hyphal elongation or any alteration in Spitzenkörper presence before, during, or after mitosis. Our findings suggest that apical growth and mitosis do not compete for internal cellular resources. Presumably, the population of cytoplasmic microtubules involved in apical growth operates independently of that involved in mitosis.

A three-dimensional model of fungal morphogenesis based on the vesicle supply center concept.

We developed a three-dimensional model of hyphal morphogenesis under the same basic assumption used for the construction of a two-dimensional model. Namely, that the polarized growth of tubular cells (hyphoids) arises from a gradient of wall-building vesicles generated by a vesicle supply center (VSC). Contrary to the 2-D mathematical formulation, the three-dimensional derivation led to an indetermination whose solution required defining a priori the pattern of expansion of the wall, i.e. defining the overall spatial movement of the wall as the newly inserted wall elements displace the existing wall fabric. The patterns of wall expansion can be described by tracing the movement of marker points on the cell surface (point trajectories). Point trajectories were computed for three different modes of wall expansion of the VSC-generated hyphoids: orthogonal, isometric, and rotational. The 3-D VSC models allowed us to either stipulate or calculate the degree of anisotropy for each type of wall expansion. Wireframe models were built to visualize growth anisotropy in each model. Although the overall shape of the three hyphoid models is similar, they differ substantially in point trajectories and anisotropy. Point trajectories are experimentally testable and were the basis for the conclusion that hyphae grow in orthogonal fashion. (Bartnicki-Garcia et al., 2000. Biophys. J.79, 2382-2390.)

Mapping the growth of fungal hyphae: orthogonal cell wall expansion during tip growth and the role of turgor.

By computer-enhanced videomicroscopy, we mapped the trajectory of external and internal cell surface markers in growing fungal hyphae to determine the pattern of cell wall expansion during apical growth. Carbon particles (India ink) were chosen as external markers for tip expansion of Rhizoctonia solani hyphae. Irregularities in the growing apical walls of R. solani served as internal markers. Marker movement was traced in captured frames from the videotaped sequences. External and internal markers both followed orthogonal trajectories; i.e., they moved perpendicular to the cell surface regardless of their initial position in the hyphal apex. We found no evidence that the tip rotates during elongation. The discovery that the cell wall of a growing hypha expands orthogonally has major repercussions on two fronts: 1) It supports the long-held view that turgor pressure is the main force driving cell wall expansion. 2) It provides crucial information to complete the mathematical derivation of a three-dimensional model of hyphal morphogenesis based on the vesicle supply center concept. In three dimensions, the vesicle gradient generated by the vesicle supply center is insufficient to explain shape; it is also necessary to know the manner in which the existing surface is displaced during wall expansion.

Glucans, walls, and morphogenesis: On the contributions of J. G. H. Wessels to the golden decades of fungal physiology and beyond.

This is a collection of impressions on the career of J. G. H. Wessels and his work in the areas of cell wall metabolism and apical morphogenesis. It highlights the finding of massive cell wall glucan metabolism during differentiation, the discovery of covalent linkages between wall polymers, the changes in chemical and physical properties of the wall at the fungal apex, and the steady-state model for tip growth. A tandem VSC-SS model for hyphal morphogenesis is proposed that combines the spatial control of wall synthesis provided by the vesicle supply center model with the temporal regulation intrinsic in Wessels's steady-state model.

What determines growth direction in fungal hyphae?

We used high-resolution video microscopy and image analysis to map the trajectory of the Spitzenkörper in growing hyphae of Neurospora crassa and to correlate it with growth directionality. The Spitzenkörper followed a tortuous trajectory produced by a dominant forward motion accompanied by frequent, transverse oscillations. In hyphae with a fixed growth direction, the regression line of the Spitzenkörper trajectory corresponded to the longitudinal axis of the hypha. A permanent change in growth direction, i.e., the establishment of a new growth axis, was correlated with a sustained shift in Spitzenkörper trajectory away from the existing cell axis. In meandering hyphae, changes in growth directionality occurred somewhat erratically but there was a strong compensatory tendency reversing directional shifts and maintaining an overall fixed direction of growth. Although external factors greatly affect hyphal growth direction (tropisms), they are probably not the primary determinants of growth directionality. Inhibitors of microtubules, but not of actin microfilaments, caused hyphae to lose their growth directionality-providing support for the idea that Spitzenkörper trajectory is determined internally by a growing scaffolding of cytoplasmic microtubules. The meandering morphology of N. crassa hyphae was duplicated by computer simulation in support of the idea that hyphal morphogenesis is controlled by the position of the Spitzenkörper functioning as a vesicle supply center.

Analysis of the role of the Spitzenkörper in fungal morphogenesis by computer simulation of apical branching in Aspergillus niger.

High-resolution video microscopy, image analysis, and computer simulation were used to study the role of the Spitzenkörper (Spk) in apical branching of ramosa-1, a temperature-sensitive mutant of Aspergillus niger. A shift to the restrictive temperature led to a cytoplasmic contraction that destabilized the Spk, causing its disappearance. After a short transition period, new Spk appeared where the two incipient apical branches emerged. Changes in cell shape, growth rate, and Spk position were recorded and transferred to the FUNGUS SIMULATOR program to test the hypothesis that the Spk functions as a vesicle supply center (VSC). The simulation faithfully duplicated the elongation of the main hypha and the two apical branches. Elongating hyphae exhibited the growth pattern described by the hyphoid equation. During the transition phase, when no Spk was visible, the growth pattern was nonhyphoid, with consecutive periods of isometric and asymmetric expansion; the apex became enlarged and blunt before the apical branches emerged. Video microscopy images suggested that the branch Spk were formed anew by gradual condensation of vesicle clouds. Simulation exercises where the VSC was split into two new VSCs failed to produce realistic shapes, thus supporting the notion that the branch Spk did not originate by division of the original Spk. The best computer simulation of apical branching morphogenesis included simulations of the ontogeny of branch Spk via condensation of vesicle clouds. This study supports the hypothesis that the Spk plays a major role in hyphal morphogenesis by operating as a VSC-i.e., by regulating the traffic of wall-building vesicles in the manner predicted by the hyphoid model.

Apical branching in a temperature sensitive mutant of Aspergillus niger.

An apical branching, temperature-sensitive, mutant of Aspergillus niger (ramosa-1) was isolated by UV mutagenesis. Ramosa-1 has a wild type morphology at 23 degrees C, but branches apically when shifted to 34 degrees C. The cytological events leading to apical branching were recorded by video-enhanced phase contrast microscopy. The first event was a momentary, localized, cytoplasmic contraction lasting approximately 1 s. This contraction was seen as a sudden unidirectional movement of visible organelles (mitochondria, spheroid bodies) toward the hyphal apex. During the contraction, there was a transitory sharp increase in refractive index in a localized area of cytoplasm in the apex or subapex of the cell. Within 5 s, the Spitzenkörper retracted from its normal position next to the apical pole and disappeared from view 20 to 50 s later. Hyphal elongation rate diminished sharply, and the typical distribution of organelles at the hyphal tip was disturbed. After 210-240 s, organelle distribution returned to normal, polarized growth resumed, but instead of one Spitzenkörper two new Spitzenkörper appeared, each giving rise to an apical branch. The second branch Spitzenkörper appeared with a 60- to 100-s delay. We did not observe the original Spitzenkörper dividing in two; instead, the new Spitzenkörper arose de novo from vesicle clouds that formed in the apical region next to the future site of branch emergence. In all instances that we examined, the dislocation and disappearance of the Spitzenkörper was preceded by cytoplasmic contractions. We therefore suspect the existence of an intimate connection between the cytoskeletal network and the Spitzenkörper. Accordingly, we propose that the apical branching phenotype in ramosa-1 is triggered by a molecular event that induces a transient alteration in cytoskeleton organization.

Evidence that Spitzenkörper behavior determines the shape of a fungal hypha: a test of the hyphoid model.

Hyphae of the fungus Rhizoctonia solani have a characteristic Spitzenkörper in their growing tips and a cell shape described by the mathematical hyphoid equation. A mild disturbance of hyphae growing in a slide culture chamber on a microscope stage caused the Spitzenkörper to move away from its usual position next to the apical pole and wander briefly inside the apical dome. Hyphal elongation rate declined abruptly, and the apex became rounded and increased in diameter. As the Spitzenkörper migrated back to its polar position, rapid cell elongation resumed, and the contour of the growing hyphal tip returned to the typical hyphoid shape. The brief dislocation of the Spitzenkörper left a permanent bulge in the hyphal profile. This morphogenetic sequence was mimicked by computer simulation, based on the hyphoid equation which relates the generation of hyphal shape to the linear displacement of a vesicle supply center (VSC). The VSC was programmed to retrace the observed movements of the Spitzenkörper during the above sequence. The resulting similarity of shape between real and computer-simulated cells reinforces the mathematical prediction that the Spitzenkörper acts as a VSC and that its continuous linear advancement generates a typical hyphal tube with the characteristic hyphoid shape. Accordingly, the hyphoid model and its VSC concept provide a plausible hypothesis to explain the cellular basis of polarized growth of fungal hyphae.

Pulsed growth of fungal hyphal tips.

Somatic fungal hyphae are generally assumed to elongate at steady linear rates when grown under constant environmental conditions with ample nutrients. However, patterns of pulsed hyphal elongation were detected during apparent steady growth of hyphal tips in fungi from several major taxonomic groups (Oomycetes, Pythium aphanidermatum and Saprolegnia ferax; Zygomycetes, Gilbertella persicaria; Deuteromycetes, Trichoderma viride; Ascomycetes, Neurospora crassa and Fusarium culmorum; Basidiomycetes, Rhizoctonia solani). Growing hyphal tips were recorded with video-enhanced phase-contrast microscopy at high magnification, and digital images were measured at very short time intervals (1-5 s). In all fungi tested, the hyphal elongation rate was never perfectly steady but fluctuated continuously with alternating periods of fast and slow growth at more or less regular intervals. Pulsed growth was observed in fungi differing in cell diameter, overall growth rate, taxonomic position, and presence and pattern of Spitzenkörper organization, suggesting that this is a general phenomenon. Frequency and amplitude of the pulses varied among the test organisms. T. viride and N. crassa showed the most frequent pulses (average of 13-14 per min), and F. culmorum the least frequent (2.7 per min). Average pulse amplitude varied from 0.012 microns/s for F. culmorum to 0.068 microns/s for G. persicaria. In F. culmorum and T. viride, the fast phase of the growth pulses was correlated with the merger of satellite Spitzenkörper with the main Spitzenkörper. These findings are consistent with a causal relationship between fluctuations in the overall rate of secretory vesicle delivery/discharge at the hyphal apex and the fluctuations in hyphal elongation rate.

Subcellular localization, abundance and stability of chitin synthetases 1 and 2 from Saccharomyces cerevisiae.

The existence of more than one chitin synthetase in fungal cells poses the question of whether these enzymes have similar or different localization. The subcellular distribution of chitin synthetases 1 and 2 (Chs1 and Chs2) was determined in cell-free extracts of Saccharomyces cerevisiae fractionated by sucrose density gradient sedimentation. Chs1 was examined in two strains: ATCC 26109, a wild-type strain, and D3C (MAT alpha ura3-52). Chs2 was investigated in a strain (D3B) freed of Chs1 by gene disruption (MATa his4 ura3-52 chs1::URA3). A prolonged, strong centrifugation (20 h at 265000 g) was necessary to cleanly resolve two major populations of chitin synthetase particles: chitosomes (a population of microvesicles of low buoyant density, d = 1.15 g ml-1) and plasma membrane (a population of vesicles of high buoyant density, d = 1.21 g ml-1). Chs1 and Chs2 were both present in chitosomes and plasma membrane, but the relative distribution of each chitin synthetase in these two membranous populations varied. Chs2 was much less abundant than Chs1 and required Co2+ rather than Mg2+ as a cofactor. A salient finding was the high sensitivity of chitosomal Chs2 to high centrifugal forces. The subcellular distribution of 1,3-beta-glucan synthetase was the same in the three strains studied, i.e. unaffected by the presence or absence of Chs1. Culture conditions affected the profiles of chitin and glucan synthetases: the relative abundance of Chs1 in chitosomes or plasma membrane was quite different in cells grown on two different media but the buoyant density was not affected; in contrast, there was shift in the buoyant density of the two peaks of 1,3-beta-glucan synthetase. We concluded that the subcellular localization of Chs1 and Chs2 remains the same despite genetic and other differences in the properties of these enzymes. We confirmed that 1,3-beta-glucan synthetase and chitin synthetase exhibit a partially different subcellular distribution-an indication that these two enzymes are mobilized through different secretory pathways.

An electron microscope and electron diffraction study of the effect of calcofluor and congo red on the biosynthesis of chitin in vitro.

The structure of chitin made in vitro by chitin synthetase was studied by electron microscopy and electron diffraction. Two different forms of chitin synthetase from the fungus Mucor rouxii were tested: chitosomes and 16 S particles. The long chitin fibrils produced by chitosomes had a high degree of crystallinity as revealed by electron diffraction. Specimen regions made of largely parallel microfibril bundles produced distinct fiber diagrams, an indication that the chitin chains were aligned along the fibril axis. Microdiffractometry of the shorter chitin crystals synthesized by 16 S particles also showed a similar alignment of chitin chains. Calcofluor and Congo red were powerful inhibitors of chitin synthetase and had profound effects on the color, macroscopic texture, electron microscopic morphology, and crystal structure of the biosynthesized chitin. Chitin made in the presence of Congo red had a bright red color; the one made in the presence of Calcofluor was strongly fluorescent and had a distinctly blue hue when illuminated by daylight. The dyes were tightly bound to the chitin and could not be removed by washing with water or ethanol. At low dye concentration, a mixture of two kinds of crystals was produced by 16 S particles: some were of the same dimensions as those made in the absence of dyes, but others were much thinner. At high dye concentration, there were only thin crystals. With increasing concentrations of Calcofluor or Congo red, the typical electron diffraction reflections of alpha-chitin, particularly the strong equatorial band at 0.466 nm became fainter and a new additional reflection centered at 0.40 nm arose as the dominant feature of the patterns. We regard the gel-like material, synthesized at highly inhibitory dye concentrations, as an apposition complex where the dye does not form part of the crystal structure of chitin and the bulk of the complex consists of molecular stacks of dye associated with nascent chitin chains or narrow chitin microfibrils.

The arrangement of F-actin and microtubules during germination of Mucor rouxii sporangiospores.

The distribution of F-actin microfilaments and microtubules was analyzed in germinating sporangiospores of Mucor rouxii by labeling with rhodamine-tagged phalloidin and by immunofluorescence microscopy. The transition from isodiametrical to apical growth was accompanied by a switch from uniform distribution of F-actin patches to a polarized accumulation of F-actin material at the germ tube tips. Immunoblotting of cell-free extracts of M. rouxii with a monoclonal anti-porcine alpha-tubulin antibody (TU-01) disclosed two discrete bands of alpha-tubulin suggesting the existence of two alpha-tubulin genes in this fungus. Immunofluorescence microscopy of germinating cells stained with the same antibody revealed an elaborate network of cytoplasmic microtubules that persisted during the entire germination process and extended into the apex of the germ tube. Although their precise roles remain undetermined, the observed arrangement of cytoskeletal elements during germination is consistent with their presumed involvement in cell wall morphogenesis: the long axial microtubules serving as long-distance conveyors of wall-building vesicles to the apical region while the concentrated F-actin patches mark the participation of microfilaments in the zone of intense vesicle exocytosis at the hyphal apex.

Unexpected destruction of chitosomal chitin synthetase by an endogenous protease during sucrose density gradient purification.

Because of their intrinsic low buoyant density, chitosomes can be separated from crude cell homogenates (1000 g or 35,000 g supernatants) of Mucor rouxii by isopycnic sedimentation in sucrose density gradients. To accelerate and simplify the isolation of chitosomes, we centrifuged the cell-free extracts at ultrahigh speed (in a fixed-angle rotor at forces up to 311,000 g Rav) and found that the duration of centrifugation was critical. Prolonged centrifugation at ultrahigh speed caused severe distortion of the chitin synthetase profile in the gradient as the peak of chitosomal chitin synthetase nearly disappeared. We traced the problem to a soluble protease(s) that moved into the chitosome band during protracted centrifugation and destroyed the chitin synthetase activity. The interfering protease was a soluble protein with a sedimentation coefficient of 4.6 S and a pH optimum of 7-7.5, and it was sensitive to PMSF (phenylmethylsulfonyl fluoride), indicating that it was a serine protease. Unlike other proteases, it destroyed chitin synthetase but did not activate the chitin synthetase zymogen. The interfering protease could be eliminated either by adding PMSF to the cells immediately after breakage or by removing the upper part of the sucrose gradient midway through the centrifugation of the cell-free extract and then completing the sedimentation with the 'decapitated' gradient.

Chitosomes and chitin synthetase in the asexual life cycle of Mucor rouxii: spores, mycelium and yeast cells.

To help understand the subcellular machinery responsible for cell wall formation in a fungus, we determined the abundance and subcellular distribution of chitin synthetase (chitin synthase, EC 2.4.1.16) and chitosomes in the asexual life cycle of Mucor rouxii. Cell-free extracts of ungerminated sporangiospores, hyphae/mycelium in exponential and stationary phase, and yeast cells were fractionated by isopycnic centrifugation in sucrose density gradients. The total amount of chitin synthetase per cell increased exponentially during aerobic germination of spores. In all developmental stages, the profile of chitin synthetase activity encompassed a broad range of sucrose density (d = 1.12-1.22) with two distinct zones: a low-density chitosome zone (d = approx. 1.12-1.16) and a high-density, mixed-membrane zone (d = approx. 1.16-1.22). Chitosomes were a major reservoir of chitin synthetase in all stages of the life cycle, including ungerminated spores. Two kinds of chitin synthetase profiles were recognized and correlated with the growth state. In nongrowing cells (ungerminated sporangiospores and stationary-phase mycelium), the profile was skewed toward lower densities with a sharp chitosome peak at d = 1.12-1.13. In actively growing cultures (aerobic mycelium or anaerobic yeast cells), the entire profile of chitin synthetase was displaced toward higher densities; the average buoyant density of chitosomes was higher (d = 1.14-1.16), and more chitin synthetase was associated with denser (d = 1.16-1.23) membrane fractions. In all life cycle stages, chitosomal chitin synthetase was almost completely zymogenic. In contrast to the enzyme from spores or from growing cells, samples of chitosomal chitin synthetase from stationary-phase mycelium were unstable and contained a high proportion of larger vesicles in addition to the typical microvesicles. The presence of chitosomes in ungerminated spores indicates that these cells are poised to begin synthesizing somatic (= vegetative) cell walls at the onset of germination. The increased buoyant density of chitosomes in actively growing cultures suggests that the composition of these microvesicles changes significantly as they mobilize chitin synthetase to the cell surface.

Sedimentation properties of chitosomal chitin synthetase from the wild-type strain and the 'slime' variant of Neurospora crassa.

Marked differences in the pattern of sedimentation of cellular structures were observed after isopycnic centrifugation of crude cell-free preparations from the Neurospora crassa wall-less 'slime' variant and mycelial wild-type strain. Kinetic studies of particle sedimentation showed that the various types of subcellular components, as revealed by turbidity, UV absorption, polypeptide patterns, and chitin synthetase activity determinations, sediment independently of one another. An important feature was the finding that chitin synthetase from 'slime' peaked at a median specific gravity of 1.1201 +/- 0.0036, whereas that from wild-type strain sedimented at a higher buoyant density (specific gravity 1.1349 +/- 0.0024). Different cultivation conditions or cell breakage procedures (osmotic lysis or ballistic disruption) did not seem to affect this sedimentation behavior. Electron microscopy revealed the presence of chitosomes (microvesicles containing chitin synthetase) in the chitin synthetase activity peaks obtained after isopycnic centrifugation of cell-free extracts from 'slime' and wild-type strains. The discrepancy in buoyant density of chitin synthetases from both N. crassa strains might point to inherent differences in chemical composition of the chitosomal microvesicles. In any case, the lower buoyant density of 'slime' chitosomes appears to be one of several major alterations in sedimentation behavior of subcellular structures. These alterations might be related to the inability of 'slime' to make a cell wall.

Localization of chitin synthetase in cell-free homogenates of Saccharomyces cerevisiae: chitosomes and plasma membrane.

We describe an improved method for fractionating cell-free extracts of Saccharomyces cerevisiae to separate its membranous components by a combination of isopycnic and velocity sedimentations. These procedures were used to examine the subcellular distribution of chitin synthetase (chitin-UDP acetylglucosaminyltransferase; EC 2.4.1.16) in homogenates from exponentially growing walled cells of a wild-type strain of yeast. Chitin synthetase (Chs1) activity was mainly found in two distinct vesicle populations of nearly equal abundance but with markedly different buoyant densities and particle diameters. One population contained 45-65% of the total chitin synthetase and was identified as chitosomes because of microvesicular size (median diameter = 61 nm) and characteristic low buoyant density (1.15 g/ml); it also lacked 1,3-beta-glucan synthetase activity. The second population (35-55%) was identified as plasma membrane because of its high buoyant density (1.22 g/ml), large vesicle size (median diameter = 252 nm), and presence of vanadate-sensitive ATPase. This fraction cosedimented with the main peak of 1,3-beta-glucan synthetase. A third, minor population of chitin synthetase particles was also detected. Essentially all of the chitin synthetase in the two vesicle populations was zymogenic; therefore, we regard these vesicles as precursors of the final active form of chitin synthetase whose location in the cell has yet to be unequivocally determined.

Chitosomes from the wall-less "slime" mutant of Neurospora crassa.

Cell-free extracts from the wall-less slime mutant of Neurospora crassa and the mycelium of wild type exhibit similar chitin synthetase properties in specific activity, zymogenicity and a preferential intracellular localization of chitosomes. The yield of chitosomal chitin synthetase from slime cells was essentially the same irrespective of cell breakage procedure (osmotic lysis or ballistic disruption)--an indication that chitosomes are not fragments of larger membranes produced by harsh (ballistic) disruption procedures. The plasma membrane fraction, isolated from slime cells treated with concanavalin A, contained only a minute portion of the total chitin synthetase of the fungus. Most of the activity was in the cytoplasmic fraction; isopycnic sedimentation of this fraction on a sucrose gradient yielded a sharp band of chitosomes with a buoyant density = 1.125 g/cm3. Approximately 76% of the total chitin synthetase activity of the slime mutant was recovered in the chitosome band. Because of their low density, chitosomes could be cleanly separated from the rest of the membranous organelles of the fungus. Apparently, the lack of a cell wall in the slime mutant is not due to the absence of either chitosomes or zymogenic chitin synthetase.

The co-ordination of chitosan and chitin synthesis in Mucor rouxii.

Chitin synthetase preparations from cell walls and chitosomes of the fungus Mucor rouxii were tested for their ability to synthesize chitosan when incubated with uridine diphosphate N-acetyl-D-glucosamine in the presence of chitin deacetylase. The most effective chitin synthetase preparation was one dissociated from cell walls with digitonin. The rate of chitosan synthesis by the wall-dissociated chitin synthetase was about three times that of an equivalent amount of cell walls. The chitosan-synthesizing ability of chitosomes was relatively low, but was more than tripled by treatment with digitonin. Presumably, digitonin improves chitosan yields of dissociating chitin synthetase. The dissociated enzyme would produce dispersed chitin chains that could be attacked by chitin deacetylase before they have time to crystallize into microfibrils. The regulation of chitin and chitosan syntheses in vivo may be determined by the organization of chitin synthetase molecules at the cell surface. Those molecules that remain organized as a complex, similar if not identical to that found in chitosomes, would produce mainly chitin. Chitosan would be preferentially produced by chitin synthetase molecules which are dispersed upon reaching the cell surface.

Polyuronide biosynthesis by cell-free extracts of Mucor rouxii.

Cell-free extracts from Mucor rouxii contain enzymes that catalyse the synthesis of uridine diphosphate glucuronic acid (UDPGlcA) from UDPglucose and the incorporation of glucuronic acid from UDPGlcA into polymer(s). Two different polyuronide fraction isolated from the cell walls of this fungus were used as primers. Mucoran, a heteropolymer, was much more efficient than mucoric acid, which is largely a homopolymer of D-glucuronic acid. The primer ability of native cell walls was comparable to that of mucoric acid. Most of the glucuronosyltransferase activity in the cell-free extract was found in a 20000 g particulate fraction. Optimum pH for polyuronide synthesis was 7.0. Mn2+ or Mg2+ stimulated incorporation of GlcA. The products synthesized from mucoric acid and mucoran primers were different and yielded different disaccharides upon hydrolysis.