Melon phloem-sap proteome: developmental control and response to viral infection.

In addition to small molecules such as sugars and amino acids, phloem sap contains macromolecules, including mRNA and proteins. It is generally assumed that all molecules in the phloem sap are on the move from source to sink, but recent evidence suggests that the macromolecules' direction of movement can be controlled by endogenous plant mechanisms. To test the hypothesis that the phloem-sap protein profile is affected by local metabolic activities, we analyzed the phloem-sap proteome in young and mature tissues of melon plants. We also examined the effect of cucumber mosaic virus (CMV) infection and expression of CMV movement protein in transgenic melon plants on the phloem protein profile. Sap collected from cut sections of young stems or petioles contained specific proteins that were absent from sap collected from mature stems or petioles. Most of these proteins were involved in defense response and protection from oxidative stress, suggesting that they play a role in maintaining safe activity of the sieve tubes in young tissues. Phloem sap collected from CMV-infected plants and transgenic plants expressing the CMV movement protein contained only a few additional proteins with molecular masses of 18 to 75 kDa. Here again, most of the additional proteins were associated with stress responses. Our study indicated that the proteome of phloem sap is dynamic and under developmental control. Entry and exit of proteins from the sieve tube can be regulated at the tissue level. Moreover, the plant can maintain regulation of protein trafficking from companion cells to sieve elements under viral infection or other perturbations in plasmodesmal function.

Long-distance trafficking of macromolecules in the phloem.

The fact that macromolecules such as proteins and mRNAs overcome the symplastic barriers between various tissue domains was first evidenced by the movement of plant viruses. We have recently demonstrated that viral infection disengages the symplastic restriction present between the sieve element-companion cell complex and neighboring cells in tobacco plants. As a result, green fluorescent protein, which was produced in mesophyll and bundle sheath cells, could traffic into the sieve tube and travel long distances within the vascular system. In this addendum we discuss the likely existence of a novel plant communication network in which macromolecules also act as long-distance trafficking signals. Plasmodesmata interconnecting sieve elements and companion cells as well as plasmodesmata connecting the sieve tube with neighboring cells may play a central role in establishing this communication network.

Viral infection enables phloem loading of GFP and long-distance trafficking of the protein.

It is generally accepted that viral systemic infection follows the source-to-sink symplastic pathway of sugar translocation. In plants that are classified as apoplastic loaders, the boundary between the companion cell-sieve element (CC-SE) complex and neighboring cells is symplastically restricted, and the potential passage of macromolecules between the two domains has yet to be explored. Transgenic tobacco plants expressing green fluorescence protein (GFP) and cucumber mosaic virus (CMV)-encoded proteins fused to GFP under the control of the fructose-1,6-bisphosphatase (FBPase) promoter were produced in order to localize the encoded proteins in mesophyll and bundle sheath cells and to explore the influence of viral infection on the functioning of plasmodesmata interconnecting the two domains. GFP produced outside the vascular tissue could overcome the symplastic barrier between the CC-SE complex and the surrounding cells to enter the vasculature in CMV-infected plants. Grafting of control (non-transgenic) tobacco scions to CMV-infected FBPase-GFP-expressing root stocks confirmed that GFP could move long distances in the phloem. No movement of the gfp mRNA was noticeable in this set of experiments. The ability of GFP to enter the vasculature and move long distances was also evident upon infection of the grafting plants with other viruses. These results provide experimental evidence for alteration of the functioning of plasmodesmata interconnecting the CC-SE complex and neighboring cells by viral infection to enable non-selective trafficking of macromolecules from the mesophyll into the sieve tube.