Effect of tryptophan on growth and morphology of Hansenula schneggii cells

Cell dispersion culture for the effective growth of Humicola insolens and efficient enzyme production

We have developed a method for the effective growth of Humicola insolens conducive to efficient enzyme production using a medium containing glucose as a carbon source and extruded soybean meal (ExSBM) as a nitrogen source. Enzymes from Humicola sp. hold promise for biomass degradation, especially of lignocellulosic materials such as rice straw, wood chips, and corn stover. The strain, however, is hard to disperse, so an aggregated form of the fungus in a liquid culture media is generally used, resulting in poor control of the growth process and low enzyme production. This has greatly limited the utilization of this strain, in spite of its potential as an enzyme producer. Surprisingly, the addition of ExSBM improves mycelium dispersion and enzyme production of H. insolens, and the dispersive effect is applicable to other fungi such as Trichoderma and Aspergillus sp. In contrast, defatted soybean meal not treated with an extrusion process has little effect on mycelium cohesion. It therefore appears that the specific three-dimensional structure of ExSBM arising from the extrusion process provides a favorable environment for cell growth, since the composition of ExSBM and soybean meal is essentially identical. The optimum medium for cell dispersion culture essentially consisted of 5% glucose and 0.3% ExSBM.

Physiological diversity within the Kluyveromyces marxianus species [corrected]

The Kluyveromyces marxianus strains CBS 6556, CBS 397 and CBS 712(T) were cultivated on a defined medium with either glucose, lactose or sucrose as the sole carbon source, at 30 and 37°C. The aim of this work was to evaluate the diversity within this species, in terms of the macroscopic physiology. The main properties evaluated were: intensity of the Crabtree effect, specific growth rate, biomass yield on substrate, metabolite excretion and protein secretion capacity, inferred by measuring extracellular inulinase activity. The strain Kluyveromyces lactis CBS 2359 was evaluated in parallel, since it is the best described Kluyveromyces yeast and thus can be used as a control for the experimental setup. K. marxianus CBS 6556 presented the highest specific growth rate (0.70 h(-1)) and the highest specific inulinase activity (1.65 U mg(-1) dry cell weight) among all strains investigated, when grown at 37°C with sucrose as the sole carbon source. The lowest metabolite formation and highest biomass yield on substrate (0.59 g dry cell weight g sucrose(-1)) was achieved by K. marxianus CBS 712(T) at 37°C. Taken together, the results show a systematic comparison of carbon and energy metabolism among three of the best known K. marxianus strains, in parallel to K. lactis CBS 2359.

Control of dimorphism in a biochemical variant of Candida albicans

The cellular morphology of a biochemical variant of Candida albicans could be controlled by the ratio of carbon dioxide to oxygen in the culture system or by individual amino acids. Predominantly pseudohyphal morphology was observed (i) at a CO(2) to O(2) ratio of 2:1 and (ii) without the addition of carbon dioxide, when either glycine, d- or l-ornithine, l-serine, l-methionine, l-phenylalanine, or l-tyrosine was the sole nitrogen source in the culture medium. When ammonium chloride, ammonium sulfate, l-glutamic acid, l-glutamine, or l-proline was the nitrogen source, yeastlike growth was observed in the presence or absence of CO(2). More adenosylmethionine was present in pseudohyphal than in yeastlike cells, and pseudohyphal cell wall preparations contained less methionine than cell walls from the yeastlike form. These results suggest a correlation between sulfur amino acid metabolism and dimorphism.