Polyphenoloxidase and the Respiration of Ivy Leaves

1. Polyphenoloxidase is present in ivy leaves but not in thoseof Aucuba or Euonymus.
2. Respiration of intact ivy leaves wasmarkedly stimulated bycatechol (R.Q. approximately=I), gallicacid, caffeic acid,and dihydroxyphenylalanine. The stimulationwas not relatedto injury as far as could be detected and wasnot followed byinhibition. The extra oxygen consumption representsa many timesrepeated oxidation of the amount of catechol supplied.
3. The effect of catechol on the respiration of Aucuba and Euonymusleaves was very small.
4. Cupferron and phenylthiourea, whichinhibit polyphenoloxidasein vitro, nevertheless increased respirationwhen administeredto leaves through the petiole. On the otherhand, when appliedby infiltration, cupferron did cause inhibition,but in Aucubaand Euonymus as much as in ivy.

     

Ca2+, annexins, and GTP modulate exocytosis from maize root cap protoplasts

Protoplasts isolated from root cap cells of maize were shown to secrete fucose-rich polysaccharides and were used in a patch-clamp study to monitor changes in whole-cell capacitance. Ca2+ was required for exocytosis, which was measured as an increase in cell capacitance during intracellular dialysis with Ca2+ buffers via the patch pipette. Exocytosis was stimulated significantly by small increases above normal resting [Ca2+]. In the absence of Ca2+, protoplasts decreased in size. In situ hybridization showed significant expression of the maize annexin p35 in root cap cells, differ-entiating vascular tissue, and elongating cells. Dialysis of protoplasts with maize annexins stimulated exocytosis at physiological [Ca2+], and this could be blocked by dialysis with antibodies specific to maize annexins. Dialysis with milli-molar concentrations of GTP strongly inhibited exocytosis, causing protoplasts to decrease in size. GTPgammaS and GDPbetaS both caused only a slight inhibition of exocytosis at physiological Ca2+. Protoplasts were shown to internalize plasma membrane actively. The results are discussed in relation to the regulation of exocytosis in what is usually considered to be a constitutively secreting system; they provide direct evidence for a role of annexins in exocytosis in plant cells.     

Feasibility of breast conservation after neoadjuvant taxene based chemotherapy in locally advanced breast cancer: a Prospective Phase I trial

Background

Acute cholecystitis can be the result of retention of bile in the gallbladder with possible secondary infection and ischaemia. The aim of the present study was to investigate whether internal drainage of the gallbladder could protect against the development of acute cholecystitis in a pig model.

Materials and methods

Twenty pigs were randomized to either internal drainage (drained) or not (undrained). Day 0 acute cholecystitis was induced by ligation of the cystic artery and duct together with inoculation of bacteria. Four days later the pigs were killed and the gallbladders were removed and histologically scored for the presence of cholecystitis. Bile and blood samples were collected for bacterial culturing and biochemical analyses.

Results

The histological examination demonstrated statistical significant differences in acute cholecystitis development between groups, the degree of inflammation being highest in undrained pigs. There were no differences in bacterial cultures between the two groups.

Conclusion

Internal drainage of the gallbladder protected against the development of acute cholecystitis in the present pig model. These findings support the theory that gallstone impaction of the cystic duct plays a crucial role as a pathogenetic mechanism in the development of acute cholecystitis and suggest that internal drainage may be a way to prevent and treat acute cholecystitis.     

Germination Preventing Mechanisms in Iris Seeds

The different germination behaviour of the seeds of two irises,Iris lorteti and I. atropurpurea was found to be due to thedifferent mechanical resistance of the integument, at the micropylarend, to radicle protrusion. A pressure of 135 atm was necessaryin l. lorteti seeds for radicle protrusion, while in I. atropurpurea77 atm was sufficient. In contrast Pancratium maritimum requireda pressure of only 10 atm. The outer integument of seeds ofI. lorteti was found to contain a compound which was toxic tothe germinated embryo but did not act as a germination inhibitor.Extracts of the endosperm also had a slight germination inhibitingeffect. An interaction between this weak inhibitor and the effectof the testa could not be ruled out completely. A test assayfor germination using excised embryos was developed. A methodfor germination of Iris seeds, by cutting off the outer integumentat the micropylar end, was developed and is being exploitedcommercially. Iris lorteti, Iris atropurpurea, germination, germination inhibition, embryo culture, seed coat mechanical resistance     

Regulation of Melanogenesis in Melanocytes

Melanogenesis refers to the biosynthesis of melanin pigment in pigment cells called melanocytes. Melanins are mixed biopolymers formed during a series of oxidation/reduction reactions that are initiated by the enzymatic hydroxylation of L-tyrosine to L-dopa. In living cells, melanogenesis is limited to melanosomes, the membrane bounded microscopic secretory granules of melanocytes. Melanosomes may be secreted into the environment as, for example, from the squid's ink gland; or be transferred to neighboring cells, such as the keratinocytes in human skin and hair; or they may remain within the pigment cell and change only their subcellular localization, as in the rapidly color-changing dermis of lower vertebrates. Regulation of the melanocytic phenotype involves synthesis of the biosynthetically active subcellular apparatus of melanogenesis, premelanosomes and tyrosinase, and the utilization of the final product, melanized melanosomes, in the translocation and secretory processes mentioned above. Genetic information for this regulation is stored in the nuclear genome whose expression is controlled by the intra- and extracellular environment. As premelanosomes become biosynthetically active, they mature into melanosomes by fusing with vesicles derived from the trans-Golgi network and the plasmalemma, thereby internalizing and incorporating contents and membrane components from inside the cell and the cell surface. In the process, melanosomes become acidified. The thesis pursued in this review explores the importance of the melanosome as the final common pathway of regulation of melanin biosynthesis.