Phloem loading: Sink/source vs. Productivity Symplast vs. apoplast pathways: distinguish at near the sieve element-companion cell complex apoplast: suc major selective transporter energy required: respiratory inhibitors, active loading Organic acids, hormones passive s -1.3 MPa s -3.0 MPa symplast: suc and others, such as raffinose and stachyose or transfer cells
Sucrose-H + symporter SE CC in the apoplast of phloem loading in the membrane of company cells or sieve elements dissipate proton energy to couple the uptake of sucrose
Regulating sucrose loading by the sucrose-H + symporter — are not completely clear The turgor pressure of the sieve elements below a threshold level, a compensatory increase loading? Sucrose concentration in the apoplast [Suc] apoplast ? The available No. of symporter molecules feed Suc SUT1 transcription , SUT1 and itsmRNA rapidly degrade, protein phosphorylation involved a diurnal regulation Nutrient supply— potassium availability enhance sucrose efflux into apoplast sink growth
Intermediary cells in the symplast of phloem loading ¤ diffusion ¤ raffinose, stachyose, in addition to sucrose ¤ a polymer-trapping model
The type of phloem loading is corrected with plant family and with climate herbaceous trees, shrubs, vines temperate and arid tropic and subtropic exceptions Coexist New loading ? Symplastic loading advantages?
Phloem unloading and short-distance transport — via symplast or apoplast PCMB: inhibit sucrose across membrane
The transition of a leaf from sink to source sink source depend on species, 25% → 40-50% The cessation of import and the initiation of export are independent events. The extent of maturation and sampling position Feed 14 C on source leaf for 2 h Squash The base still a sink sink leaf source leaf