Proton- and sodium-coupled phosphate transport systems and energy status of Yarrowia lipolytica cells grown in acidic and alkaline conditions

In this study we have used a newly isolated Yarrowia lipolytica yeast strain with a unique capacity to grow over a wide pH range (3.5–10.5), which makes it an excellent model system for studying H⁺- and Na⁺-coupled phosphate transport systems. Even at extreme growth conditions (low concentrations of extracellular phosphate, alkaline pH values) Y. lipolytica preserved tightly-coupled mitochondria with the fully competent respiratory chain containing three points of energy conservation. This was demonstrated for the first time for cells grown at pH 9.5–10.0. In cells grown at pH 4.5, inorganic phosphate (P_i) was accumulated by two kinetically discrete H⁺/P_i-cotransport systems. The low-affinity system is most likely constitutively expressed and operates at high P_i concentrations. The high-affinity system, subjected to regulation by both extracellular P_i availability and intracellular polyphosphate stores, is mobilized during P_i-starvation. In cells grown at pH 9.5–10, P_i uptake is mediated by several kinetically discrete Na⁺-dependent systems that are specifically activated by Na⁺ ions and insensitive to the protonophore CCCP. One of these, a low-affinity transporter operative at high P_i concentrations is kinetically characterized here for the first time. The other two, high-affinity, high-capacity systems, are derepressible and functional during P_i-starvation and appear to be controlled by extracellular P_i. They represent the first examples of high-capacity, Na⁺-driven P_i transport systems in an organism belonging to neither the animal nor bacterial kingdoms. The contribution of the H⁺- and Na⁺-coupled P_i transport systems in Y. lipolytica cells grown at different pH values was quantified. In cells grown at pH values of 4.5 and 6.0, the H⁺-coupled P_i transport systems are predominant. The contribution of the Na⁺/P_i cotransport systems to the total cellular P_i uptake activity is progressively increased with increasing pH, reaching its maximum at pH 9 and higher. Received: 15 December 2000/Revised: 14 May 2001     

Presence of organic sources of nitrogen is critical for filament formation and pH-dependent morphogenesis in Yarrowia lipolytica

Yeast dimorphism is an attractive model for the study of cell morphogenesis and differentiation. The non-conventional yeast Yarrowia lipolytica was chosen to characterise the regulation of dimorphic transition by extracellular pH and by the presence of organic sources of nitrogen. Organic nitrogen sources appear to be required for the morphogenic effect of pH. Two sets of mutants defective in either pH-dependent or nitrogen source-dependent signalling pathway were analysed. The results suggest that the latter but not the former is required for both normal filament formation on solid medium and pH-dependent dimorphic behaviour of Y. lipolytica in liquid medium. We propose that in this organism pH affects the formation of hyphae indirectly by modulation of availability and/or utilisation of transportable sources of nitrogen.     

A new alkalitolerant <Emphasis Type="Italic">Yarrowia lipolytica</Emphasis> yeast strain is a promising model for dissecting properties and regulation of Na<Superscript>+</Superscript>-dependent phosphate transport systems

A newly isolated osmo-, salt-, and alkalitolerant Yarrowia lipolytica yeast strain is distinguished from other yeast species by its capacity to grow vigorously at alkaline pH values (9.7), which makes it a promising model organism for studying Na⁺-dependent phosphate transport systems in yeasts. Phosphate uptake by Y. lipolytica cells grown at pH 9.7 was mediated by several kinetically discrete Na⁺-dependent systems specifically activated by Na⁺. One of these, a low-affinity transporter, operated at high concentrations of extracellular phosphate. The other two, high-affinity systems, maximally active in phosphate-starved cells, were repressed or derepressed depending on the prevailing extracellular phosphate concentration and pH value. The contribution of Na⁺/P_i-cotransport systems to the total cellular phosphate uptake progressively increased with increasing pH, reaching its maximum at pH 9.Translated from Biokhimiya, Vol. 69, No. 11, 2004, pp. 1607–1615.Original Russian Text Copyright © 2004 by Zvyagilskaya, Persson.     

Membrane contact site-dependent cholesterol transport regulates Na+/K+-ATPase polarization and spermiogenesis in Caenorhabditis elegans

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Differences in epithelial morphology correlate to Na+‐transport: A study of the proximal,mid, and distal regions of the coprodeum from hens on high and low NaCl diet

A study was performed to correlate regional morphology and amiloride inhibitable Na⁺‐transport in the coprodeal epithelium in hens, Gallus domesticus, on low‐NaCl diet and in controls. Proximal (close to colon), mid and distal (close to urodeum) regions were examined using light microscopy, transmission‐ and scanning electron microscopy. Na⁺‐transport was measured electrophysiologically in Ussing‐chambers in the proximal and distal regions. The epithelium, simple and columnar, is composed of absorptive intestinal epithelial cells, goblet cells, brush cells, migrating lymphoid cells, and entero‐endocrine cells. Brush cells, identified in avians for the first time, occur in highest number in the proximal part of the coprodeum in low‐NaCl hens. Na⁺‐transport is high in the low‐NaCl hens, ranging from 347μA/cm² (proximal) to 187μA/cm² (distal). In control hens, which correspond to hens on high‐NaCl diet, it is low in all regions (0–4 μA/cm²). Absorptive intestinal epithelial cells as well as brush cells adapt to variations in transepithelial Na⁺‐transport by regulating height and packing density of their microvilli, number, size, and localization of apical vesicles, and the width of the intercellular space. Regional differences in the epithelial cell composition and ultrastructure are closely correlated to transepithelial Na⁺‐transport but only in low‐NaCl hens, as controls do not show these variations. J. Morphol. 239:75–86, 1999. © 1999 Wiley‐Liss, Inc.