Studies on the possible occurrence of actomyosin-like proteins in phloem

Heterogeneity in phloem protein complements from different species : Consequences of hypotheses concerned with P-protein function

Protein subunits present in phloem exudate from 17 cultivars, 5 species and 3 genera of the Cucurbitaceae have been fractionated by SDS-gel electrophoresis. The degree of difference in the phloem protein patterns appears to reflect the taxonomic relationships of the plants: there were major differences among genera, significant differences and similarities among species, and relatively few differences among cultivars of a single species. A representative of another family (Acer pseudoplatanus; Aceraceae) provided a completely different electrophoretic pattern. Each plant displayed a consistent protein pattern, irrespective of the organ from which exudate was obtained or the age and physiological status of the plant. Neither complete etiolation nor transition to the flowering phase effected any change in phloem proteins. The differences in phloem proteins between plants and the unusual properties of major subunits from different protein complements, render improbable many of the present ideas concerning the origin and function of P-protein.

The microscopy of P-protein filaments in freeze-etched sieve pores : Brownian motion limits resolution of their positions

Intact vascular bundles from Nymphoides peltata (S.G. Gmel.) O. Kuntze, shown to have translocated carbon-14, were freeze-fractured and etched for electron microscopy. The interpretation of freezefractured and etched sieve pores and P-protein filaments seen in them is discussed. The entire widths of most of the sieve pores seen contained filaments separated by less than 100 nm. Their arrangement indicates too high a resistance to flow for pressure flow alone to drive translocation at known rates; pumps would be necessary at places along sieve tubes. However, calculations are presented to show that during the time taken to fix pores, by fast freezing or chemically, the filaments in them could rearrange and move further by Brownian and other motion than the distances between filaments which we need to measure. These calculations show that it is not possible, by microscopy alone, to answer the outstanding question "How are filaments arranged in translocating sieve pores?" with enough certainty to tell us whether pressure flow is adequate to explain translocation where filaments are present. The calculations are relevant also to microscopy of other cell structures which may move.

Is P-protein actin-like?-not yet

Microfilaments associated with cytoplasmic streaming in Nitella flexilis internodes can be decorated with heavy meromyosin (HMM) from rabbit, both in vitro in cytoplasmic suspensions, and in situ in glycerinated cell segments. The bound HMM consists of clearly discernible, polarized arrowheads in a regular repeat of 360-380 Å that are similar to those produced on F-actin. In contrast, similar arrowheads or decorations are not evident on P-protein filaments in sieve elements of glycerinated hypocotyl segments of Phaseolus vulgaris L. treated with HMM. Thus, these results contradict a recent claim that P-protein binds HMM and is actin-like. The mass of other evidence now available from diverse studies indicating that P-protein does not consist of actin or tubulin is discussed.