Root Flooding of Muskmelon (Cucumis melo L.) Affects Fruit Sugar Concentration But Not Leaf Carbon Exchange Rate

Flooding the roots of greenhouse-grown muskmelon (Cucumis meloL. cv. Noy Yizreel) plants for 4 days reduced sucrose accumulation36% in the inner mesocarp and 88% in the outer mesocarp of developingfruit. Concentration of the translocated sugars raffinose andstachyose were also lower in fruit on flooded plants than inthose from nonflooded plants. In contrast, fruit hexose concentrationwas similar in both flooded and nonflooded plants. There wasno alteration in activities of enzymes associated with sucrosemetabolism in the fruit which could explain the decreased sucroseconcentration. Four days of root flooding caused no reductionin leaf carbon exchange rate or assimilate export rate, indicatingthat the reduction in fruit sucrose accumulation was not dueto source limitation. Root respiration, measured as CO₂ evolution,was approximately 30% lower in anaerobic roots than in aerobicroots. When viewed as carbohydrate consumed, a doubling of glycolyticactivity occurred in the anaerobic root mass. Increased demandfor carbohydrates by anaerobic roots may lead to a reductionin translocated carbohydrates available for sucrose biosynthesisin the developing fruit. (Received August 29, 1990; Accepted February 21, 1991)     

INFLUENCE OF GROWTH STATUS AND NUTRIENTS ON EXTRACELLULAR POLYSACCHARIDE SYNTHESIS BY THE SOIL ALGA CHLAMYDOMONAS MEXICANA (CHLOROPHYCEAE)1

Increased levels of nitrogen in liquid growth medium bring about increased growth and a delay in extracellular polysaccharide production by Chlamydomonas mexicana Lewin on a per-cell basis. Addition of nitrogen to stationary phase cultures causes renewed growth and a temporary lag in polysaccharide synthesis until growth again ceases. Removal of nitrogen terminates growth, causing an immediate increase in polysaccharide synthesis. Phosphate-starved cells show a response similar to nitrogen-starved cells, indicating that the beginning of stationary phase and not nitrogen depletion causes the stimulation in extracellular polysaccharide synthesis. As similar results are assumed to occur on soil, the significance of this response is discussed.     

GROWTH AND POLYSACCHARIDE PRODUCTION BY THE GREEN ALGA CHLAMYDOMONAS MEXICANA (CHLOROPHYCEAE) ON SOIL1

The polysaccharide producing soil alga Chlamydomonas mexicana Lewin was grown on soil surfaces in a growth chamber, with cell number and total polysaccharide measured weekly. Cell growth was pronounced, reaching an excess of 10⁷ cells · cm^?2 within one week. Polysaccharide production was also pronounced, with similar amounts of polysaccharide synthesized whether or not the cells were continuously given nutrients. Polysaccharide synthesis increased once the cells slowed in their growth, as in previous work with the cells in liquid medium.     

VISCOUS POLYSACCHARIDE AND STARCH SYNTHESIS IN RHODELLA RETICULATA (PORPHYRIDIALES,RHODOPHYTA)1

Rhodella reticulata Deason, Butler and Rhyne produces copious amounts of a viscous polysaccharide (VP) during growth in batch cultures. The VPs accumulated on the cell surface and in the culture medium once cells ceased growth; starch concurrently accumulated within the cells. Light-saturated ¹⁴C-uptake declined steadily as the cells aged. Net synthesis rates for starch and mucilage were two- and four-fold lower, respectively, in non-growing cells than in growing cells, while the relative partitioning of newly-fixed carbon into these materials was not different. These data suggest that total photosynthetic loading, rather than partitioning into one specific pool, controls cellular synthesis rates. No preferential synthesis of VPs occurred during the stationary phase. The findings have important implications for the commercial production of VPs.