Submergence research using Rumex palustris as a model; looking back and going forward

Flooding is a phenomenon that destroys many crops worldwide. During evolution several plant species evolved specialized mechanisms to survive short- or long-term waterlogging and even complete submergence. One of the plant species that evolved such a mechanism is Rumex palustris. When flooded, this plant species is capable to elongate its petioles to reach the surface of the water. Thereby it restores normal gas exchange which leads to a better survival rate. Enhanced levels of ethylene, due to physical entrapment, is the key signal for the plant that its environment has changed from air to water. Subsequently, a signal transduction cascade involving at least four (classical) plant hormones, ethylene, auxin, abscisic acid, and gibberellic acid, is activated. This results in hyponastic growth of the leaves accompanied by a strongly enhanced elongation rate of the petioles enabling them to reach the surface. Other factors, among them cell wall loosening enzymes have been shown to play a role as well.     

Plant movement. Submergence-induced petiole elongation in Rumex palustris depends on hyponastic growth

The submergence-tolerant species Rumex palustris (Sm.) responds to complete submergence by an increase in petiole angle with the horizontal. This hyponastic growth, in combination with stimulated elongation of the petiole, can bring the leaf tips above the water surface, thus restoring gas exchange and enabling survival. Using a computerized digital camera set-up the kinetics of this hyponastic petiole movement and stimulated petiole elongation were studied. The hyponastic growth is a relatively rapid process that starts after a lag phase of 1.5 to 3 h and is completed after 6 to 7 h. The kinetics of hyponastic growth depend on the initial angle of the petiole at the time of submergence, a factor showing considerable seasonal variation. For example, lower petiole angles at the time of submergence result in a shorter lag phase for hyponastic growth. This dependency of the hyponastic growth kinetics can be mimicked by experimentally manipulating the petiole angle at the time of submergence. Stimulated petiole elongation in response to complete submergence also shows kinetics that are dependent on the petiole angle at the time of submergence, with lower initial petiole angles resulting in a longer lag phase for petiole elongation. Angle manipulation experiments show that stimulated petiole elongation can only start when the petiole has reached an angle of 40 degrees to 50 degrees. The petiole can reach this "critical angle" for stimulated petiole elongation by the process of hyponastic growth. This research shows a functional dependency of one response to submergence in R. palustris (stimulated petiole elongation) on another response (hyponastic petiole growth), because petiole elongation can only contribute to the leaf reaching the water surface when the petiole has a more or less upright position.     

Unequal chances for reaching 'a good old age'. Socio-economic health differences among older adults from a life course perspective

This article provides an overview of the socioeconomic inequality in physical and psychological health of older adults between 55 and 85 years of age, with a focus on the older adults whose socioeconomic status (SES) remains at a low level all their life. Data are derived from 1471 men and 1568 women, participating in the Longitudinal Aging Study Amsterdam (LASA) in 1992/1993. Based on the parental and own level of education, respondents are divided in four categories: those with a life time low level of SES, those with downward or upward mobility in SES, and those with a life time high level of SES. Logistic regression analyses showed that older adults with upward SES mobility and life time high SES, had a lower risk for functional limitations, chronic diseases (men only), 6-year mortality, depression and loneliness, compared with the older adults with life time low SES. The disadvantaged position of the low SES persons with regard to age, health and psychosocial conditions explained the SES differences in depression, but SES differences in mortality (for men) and in functional disability (for men and women) are not explained by the risk factors under study. SES differences in loneliness were attributed to differences in psychosocial conditions. Lifestyle did not add to the explanation of any of the SES differences. There were only small differences between those with a life time low SES and those with downward mobility in SES. It is concluded that a low level of education (regardless of the parental level) contributes to restricted psychosocial conditions, health problems and low well-being in old age, thereby decreasing the chances for a 'good old age' considerably.     

Reactive type II pneumocytes in bronchoalveolar lavage fluid

OBJECTIVE: To evaluate the prevalence of reactive type II pneumocytes (RPII) in bronchoalveolar lavage (BAL) fluid samples obtained from patients with various pulmonary disorders. STUDY DESIGN: Consecutive BAL fluid samples were screened for the presence of RPII on May-Grünwald-Giemsa-stained cytocentrifuge preparations. BAL fluid samples with and without RPII were compared with regard to prevalence, associated clinical diagnoses and cytologic findings. RESULTS: RPII were generally large cells with a high nuclear:cytoplasmic ratio and deeply blue-stained, vacuolated cytoplasm. Most RPII occurred in cohesive cell groups, and the vacuoles tended to be confluent. Cytologic findings associated with RPII were foamy alveolar macrophages, activated lymphocytes and plasma cells. RPII were present in 94 (21.7%) of 433 included BAL fluid samples. The highest prevalences were noted in patients with systemic inflammatory response syndrome and alveolar hemorrhage. In addition, RPII tended to occur more frequently in ventilator-associated pneumonia, Pneumocystis carinii pneumonia, extrinsic allergic alveolitis and drug-induced pulmonary disorders. In contrast, RPII were not observed in BAL fluid samples obtained from patients with sarcoidosis. CONCLUSION: RPII were prevalent in about 20% of BAL fluid specimens. They were associated mainly with conditions of acute lung injury and not observed in sarcoidosis.     

Principles behind the multifarious control of signal transduction. ERK phosphorylation and kinase/phosphatase control

General and simple principles are identified that govern signal transduction. The effects of kinase and phosphatase inhibition on a MAP kinase pathway are first examined in silico. Quantitative measures for the control of signal amplitude, duration and integral strength are introduced. We then identify and prove new principles, such that total control on signal amplitude and on final signal strength must amount to zero, and total control on signal duration and on integral signal intensity must equal -1. Collectively, kinases control amplitudes more than duration, whereas phosphatases tend to control both. We illustrate and validate these principles experimentally: (a) a kinase inhibitor affects the amplitude of EGF-induced ERK phosphorylation much more than its duration and (b) a phosphatase inhibitor influences both signal duration and signal amplitude, in particular long after EGF administration. Implications for the cellular decision between growth and differentiation are discussed.     

A new class of ubiquitin extension proteins secreted by the dorsal pharyngeal gland in plant parasitic cyst nematodes

By performing cDNA AFLP on pre- and early parasitic juveniles, we identified genes encoding a novel type of ubiquitin extension proteins secreted by the dorsal pharyngeal gland in the cyst nematode Heterodera schachtii. The proteins consist of three domains, a signal peptide for secretion, a mono-ubiquitin domain, and a short C-terminal positively charged domain. A gfp-fusion of this protein is targeted to the nucleolus in tobacco BY-2 cells. We hypothesize that the C-terminal peptide might have a regulatory function during syncytium formation in plant roots.     

A novel method for repetitive peptide synthesis in solution without isolation of intermediates.

A novel method was developed for the large-scale manufacture of peptides in solution, called DioRaSSP-Diosynth Rapid Solution Synthesis of Peptides. This method combines the advantages of the homogeneous character of classical solution-phase synthesis with the universal character and the amenability to automation inherent to the solid-phase approach. The process consists of repetitive cycles of coupling and deprotection in a permanent organic phase and is further characterized by the fact that intermediates are not isolated. Couplings are mediated by water-soluble carbodiimide. Several types of function may be applied for temporary amino protection depending on the sequence of the actual peptide, including Z, Fmoc, Msc and Nsc. Formate is the preferred hydrogen donor during hydrogenolysis of the Z function, while 1,8-diazabicyclo[5.4.0]undec-7-ene is used to deprotect Fmoc, Msc and Nsc. Morpholine is added during the deprotection of Msc and Nsc to scavenge the arising alkenes. Processes according to this highly efficient synthesis method are easy to scale up and yield products of reproducible high purity, which is guaranteed by a new quenching method for residual activated compounds, applying an anion-forming amine such as a beta-alanine ester. This ester should display a lability similar to that of the temporary amino-protecting function, allowing simultaneous deprotection of the growing peptide and the quenched compound. The DioRaSSP approach assures the completely quantitative removal of deprotected quenched compounds before the coupling step of the next cycle of the synthesis by basic aqueous (that is active) extraction, while the growing peptide remains anchored in the organic phase due to the presence of hydrophobic protecting functions.     

Par1b Induces Asymmetric Inheritance of Plasma Membrane Domains via LGN-Dependent Mitotic Spindle Orientation in Proliferating Hepatocytes

The development and maintenance of polarized epithelial tissue requires a tightly controlled orientation of mitotic cell division relative to the apical polarity axis. Hepatocytes display a unique polarized architecture. We demonstrate that mitotic hepatocytes asymmetrically segregate their apical plasma membrane domain to the nascent daughter cells. The non-polarized nascent daughter cell can form a de novo apical domain with its new neighbor. This asymmetric segregation of apical domains is facilitated by a geometrically distinct “apicolateral” subdomain of the lateral surface present in hepatocytes. The polarity protein partitioning-defective 1/microtubule-affinity regulating kinase 2 (Par1b/MARK2) translates this positional landmark to cortical polarity by promoting the apicolateral accumulation of Leu-Gly-Asn repeat-enriched protein (LGN) and the capture of nuclear mitotic apparatus protein (NuMA)–positive astral microtubules to orientate the mitotic spindle. Proliferating hepatocytes thus display an asymmetric inheritance of their apical domains via a mechanism that involves Par1b and LGN, which we postulate serves the unique tissue architecture of the developing liver parenchyma.